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Spider

January 11, 2024

For other uses, see Spider (disambiguation).

Spiders (order Araneae) are air-breathing arthropods that have eight limbs, chelicerae with fangs generally able to inject venom,[2] and spinnerets that extrude silk.[3] They are the largest order of arachnids and rank seventh in total species diversity among all orders of organisms.[4][5] Spiders are found worldwide on every continent except for Antarctica, and have become established in nearly every land habitat. As of November 2023, 51,673 spider species in 136 families have been recorded by taxonomists.[1] However, there has been debate among scientists about how families should be classified, with over 20 different classifications proposed since 1900.[6]

Spiders
Temporal range: PennsylvanianHolocene, 319–0 Ma
CyrtaucheniidaeSalticidaeTheraphosidaeNemesiidaeTetragnathidaeAtypidaeCorinnidaeEresidaeThomisidaeHexathelidaeDipluridaeOecobiidaeTheridiidaeAraneidaeSegestriidaeTitanoecidaeZoropsidaeOxyopidae
An assortment of different spiders
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Subphylum: Chelicerata
Class: Arachnida
Clade: Tetrapulmonata
Order: Araneae
Clerck, 1757
Suborders

 See Spider taxonomy.

Diversity[1]
132 families, c. 50,000 species

Anatomically, spiders (as with all arachnids) differ from other arthropods in that the usual body segments are fused into two tagmata, the cephalothorax or prosoma, and the opisthosoma, or abdomen, and joined by a small, cylindrical pedicel. However, as there is currently neither paleontological nor embryological evidence that spiders ever had a separate thorax-like division, there exists an argument against the validity of the term cephalothorax, which means fused cephalon (head) and the thorax. Similarly, arguments can be formed against use of the term abdomen, as the opisthosoma of all spiders contains a heart and respiratory organs, organs atypical of an abdomen.[7]

Unlike insects, spiders do not have antennae. In all except the most primitive group, the Mesothelae, spiders have the most centralized nervous systems of all arthropods, as all their ganglia are fused into one mass in the cephalothorax. Unlike most arthropods, spiders have no extensor muscles in their limbs and instead extend them by hydraulic pressure.

Their abdomens bear appendages that have been modified into spinnerets that extrude silk from up to six types of glands. Spider webs vary widely in size, shape and the amount of sticky thread used. It now appears that the spiral orb web may be one of the earliest forms, and spiders that produce tangled cobwebs are more abundant and diverse than orb-weaver spiders. Spider-like arachnids with silk-producing spigots (Uraraneida) appeared in the Devonian period about 386 million years ago, but these animals apparently lacked spinnerets. True spiders have been found in Carboniferous rocks from 318 to 299 million years ago, and are very similar to the most primitive surviving suborder, the Mesothelae. The main groups of modern spiders, Mygalomorphae and Araneomorphae, first appeared in the Triassic period, before 200 million years ago.

The species Bagheera kiplingi was described as herbivorous in 2008,[8] but all other known species are predators, mostly preying on insects and on other spiders, although a few large species also take birds and lizards. It is estimated that the world's 25 million tons of spiders kill 400–800 million tons of prey per year.[9] Spiders use a wide range of strategies to capture prey: trapping it in sticky webs, lassoing it with sticky bolas, mimicking the prey to avoid detection, or running it down. Most detect prey mainly by sensing vibrations, but the active hunters have acute vision, and hunters of the genus Portia show signs of intelligence in their choice of tactics and ability to develop new ones. Spiders' guts are too narrow to take solids, so they liquefy their food by flooding it with digestive enzymes. They also grind food with the bases of their pedipalps, as arachnids do not have the mandibles that crustaceans and insects have.

To avoid being eaten by the females, which are typically much larger, male spiders identify themselves to potential mates by a variety of complex courtship rituals. Males of most species survive a few matings, limited mainly by their short life spans. Females weave silk egg-cases, each of which may contain hundreds of eggs. Females of many species care for their young, for example by carrying them around or by sharing food with them. A minority of species are social, building communal webs that may house anywhere from a few to 50,000 individuals. Social behavior ranges from precarious toleration, as in the widow spiders, to co-operative hunting and food-sharing. Although most spiders live for at most two years, tarantulas and other mygalomorph spiders can live up to 25 years in captivity.

While the venom of a few species is dangerous to humans, scientists are now researching the use of spider venom in medicine and as non-polluting pesticides. Spider silk provides a combination of lightness, strength and elasticity that is superior to that of synthetic materials, and spider silk genes have been inserted into mammals and plants to see if these can be used as silk factories. As a result of their wide range of behaviors, spiders have become common symbols in art and mythology symbolizing various combinations of patience, cruelty and creative powers. An irrational fear of spiders is called arachnophobia.

Etymology

The word spider derives from Proto-Germanic *spin-þron-, literally 'spinner' (a reference to how spiders make their webs), from the Proto-Indo-European root *(s)pen- 'to draw, stretch, spin'.[10]

Description

Main article: Spider anatomy

Body plan

 
Palystes castaneus female, dorsal aspect
  1. pedipalp
  2. trichobothria
  3. carapace of prosoma (cephalothorax)
  4. opisthosoma (abdomen)
  5. eyes
    • AL (anterior lateral)
    • AM (anterior median)
    • PL (posterior lateral)
    • PM (posterior median)
Leg segments:
  1. coxa
  2. trochanter
  3. femur
  4. patella
  5. tibia
  6. metatarsus
  7. tarsus
  8. claw
  9. chelicera
 
Palystes castaneus female, ventral aspect. Nos 1 to 14 as for dorsal aspect.
  1. sternum of prosoma
  2. pedicel (also called pedicle)
  3. book lung sac
  4. book lung stigma
  5. epigastric fold
  6. epigyne
  7. anterior spinneret
  8. posterior spinneret
Legs are labelled I, II, III, IV from anterior to posterior.

Spiders are chelicerates and therefore arthropods.[11] As arthropods they have: segmented bodies with jointed limbs, all covered in a cuticle made of chitin and proteins; heads that are composed of several segments that fuse during the development of the embryo.[12] Being chelicerates, their bodies consist of two tagmata, sets of segments that serve similar functions: the foremost one, called the cephalothorax or prosoma, is a complete fusion of the segments that in an insect would form two separate tagmata, the head and thorax; the rear tagma is called the abdomen or opisthosoma.[11] In spiders, the cephalothorax and abdomen are connected by a small cylindrical section, the pedicel.[13] The pattern of segment fusion that forms chelicerates' heads is unique among arthropods, and what would normally be the first head segment disappears at an early stage of development, so that chelicerates lack the antennae typical of most arthropods. In fact, chelicerates' only appendages ahead of the mouth are a pair of chelicerae, and they lack anything that would function directly as "jaws".[12][14] The first appendages behind the mouth are called pedipalps, and serve different functions within different groups of chelicerates.[11]

Spiders and scorpions are members of one chelicerate group, the arachnids.[14] Scorpions' chelicerae have three sections and are used in feeding.[15] Spiders' chelicerae have two sections and terminate in fangs that are generally venomous, and fold away behind the upper sections while not in use. The upper sections generally have thick "beards" that filter solid lumps out of their food, as spiders can take only liquid food.[13] Scorpions' pedipalps generally form large claws for capturing prey,[15] while those of spiders are fairly small appendages whose bases also act as an extension of the mouth; in addition, those of male spiders have enlarged last sections used for sperm transfer.[13]

In spiders, the cephalothorax and abdomen are joined by a small, cylindrical pedicel, which enables the abdomen to move independently when producing silk. The upper surface of the cephalothorax is covered by a single, convex carapace, while the underside is covered by two rather flat plates. The abdomen is soft and egg-shaped. It shows no sign of segmentation, except that the primitive Mesothelae, whose living members are the Liphistiidae, have segmented plates on the upper surface.[13]

Circulation and respiration

 

Like other arthropods, spiders are coelomates in which the coelom is reduced to small areas around the reproductive and excretory systems. Its place is largely taken by a hemocoel, a cavity that runs most of the length of the body and through which blood flows. The heart is a tube in the upper part of the body, with a few ostia that act as non-return valves allowing blood to enter the heart from the hemocoel but prevent it from leaving before it reaches the front end.[16] However, in spiders, it occupies only the upper part of the abdomen, and blood is discharged into the hemocoel by one artery that opens at the rear end of the abdomen and by branching arteries that pass through the pedicle and open into several parts of the cephalothorax. Hence spiders have open circulatory systems.[13] The blood of many spiders that have book lungs contains the respiratory pigment hemocyanin to make oxygen transport more efficient.[14]

Spiders have developed several different respiratory anatomies, based on book lungs, a tracheal system, or both. Mygalomorph and Mesothelae spiders have two pairs of book lungs filled with haemolymph, where openings on the ventral surface of the abdomen allow air to enter and diffuse oxygen. This is also the case for some basal araneomorph spiders, like the family Hypochilidae, but the remaining members of this group have just the anterior pair of book lungs intact while the posterior pair of breathing organs are partly or fully modified into tracheae, through which oxygen is diffused into the haemolymph or directly to the tissue and organs.[13] The tracheal system has most likely evolved in small ancestors to help resist desiccation.[14] The trachea were originally connected to the surroundings through a pair of openings called spiracles, but in the majority of spiders this pair of spiracles has fused into a single one in the middle, and moved backwards close to the spinnerets.[13] Spiders that have tracheae generally have higher metabolic rates and better water conservation.[17] Spiders are ectotherms, so environmental temperatures affect their activity.[18]

Feeding, digestion and excretion

 
A syrphid fly captured in the web of a spider
 
Cheiracanthium punctorium, displaying fangs

Uniquely among chelicerates, the final sections of spiders' chelicerae are fangs, and the great majority of spiders can use them to inject venom into prey from venom glands in the roots of the chelicerae.[13] The families Uloboridae and Holarchaeidae, and some Liphistiidae spiders, have lost their venom glands, and kill their prey with silk instead.[19] Like most arachnids, including scorpions,[14] spiders have a narrow gut that can only cope with liquid food and two sets of filters to keep solids out.[13] They use one of two different systems of external digestion. Some pump digestive enzymes from the midgut into the prey and then suck the liquified tissues of the prey into the gut, eventually leaving behind the empty husk of the prey. Others grind the prey to pulp using the chelicerae and the bases of the pedipalps, while flooding it with enzymes; in these species, the chelicerae and the bases of the pedipalps form a preoral cavity that holds the food they are processing.[13]

The stomach in the cephalothorax acts as a pump that sends the food deeper into the digestive system. The midgut bears many digestive ceca, compartments with no other exit, that extract nutrients from the food; most are in the abdomen, which is dominated by the digestive system, but a few are found in the cephalothorax.[13]

Most spiders convert nitrogenous waste products into uric acid, which can be excreted as a dry material. Malphigian tubules ("little tubes") extract these wastes from the blood in the hemocoel and dump them into the cloacal chamber, from which they are expelled through the anus.[13] Production of uric acid and its removal via Malphigian tubules are a water-conserving feature that has evolved independently in several arthropod lineages that can live far away from water,[20] for example the tubules of insects and arachnids develop from completely different parts of the embryo.[14] However, a few primitive spiders, the suborder Mesothelae and infraorder Mygalomorphae, retain the ancestral arthropod nephridia ("little kidneys"),[13] which use large amounts of water to excrete nitrogenous waste products as ammonia.[20]

Central nervous system

The basic arthropod central nervous system consists of a pair of nerve cords running below the gut, with paired ganglia as local control centers in all segments; a brain formed by fusion of the ganglia for the head segments ahead of and behind the mouth, so that the esophagus is encircled by this conglomeration of ganglia.[21] Except for the primitive Mesothelae, of which the Liphistiidae are the sole surviving family, spiders have the much more centralized nervous system that is typical of arachnids: all the ganglia of all segments behind the esophagus are fused, so that the cephalothorax is largely filled with nervous tissue and there are no ganglia in the abdomen;[13][14][21] in the Mesothelae, the ganglia of the abdomen and the rear part of the cephalothorax remain unfused.[17]

Despite the relatively small central nervous system, some spiders (like Portia) exhibit complex behaviour, including the ability to use a trial-and-error approach.[22][23][24]

Sense organs

Eyes

Main article: Spider vision
 
This jumping spider's main ocelli (center pair) are very acute. The outer pair are "secondary eyes" and there are other pairs of secondary eyes on the sides and top of its head.[25]
 
Eyes of the jumping spider, Plexippus paykulli

Spiders have primarily four pairs of eyes on the top-front area of the cephalothorax, arranged in patterns that vary from one family to another.[13] The principal pair at the front are of the type called pigment-cup ocelli ("little eyes"), which in most arthropods are only capable of detecting the direction from which light is coming, using the shadow cast by the walls of the cup. However, in spiders these eyes are capable of forming images.[25][26] The other pairs, called secondary eyes, are thought to be derived from the compound eyes of the ancestral chelicerates, but no longer have the separate facets typical of compound eyes. Unlike the principal eyes, in many spiders these secondary eyes detect light reflected from a reflective tapetum lucidum, and wolf spiders can be spotted by torchlight reflected from the tapeta. On the other hand, the secondary eyes of jumping spiders have no tapeta.[13]

Other differences between the principal and secondary eyes are that the latter have rhabdomeres that point away from incoming light, just like in vertebrates, while the arrangement is the opposite in the former. The principal eyes are also the only ones with eye muscles, allowing them to move the retina. Having no muscles, the secondary eyes are immobile.[27]

The visual acuity of some jumping spiders exceeds by a factor of ten that of dragonflies, which have by far the best vision among insects.[citation needed] This acuity is achieved by a telephotographic series of lenses, a four-layer retina, and the ability to swivel the eyes and integrate images from different stages in the scan.[citation needed] The downside is that the scanning and integrating processes are relatively slow.[22]

There are spiders with a reduced number of eyes, the most common having six eyes (example, Periegops suterii) with a pair of eyes absent on the anterior median line.[28] Other species have four eyes and members of the Caponiidae family can have as few as two.[29] Cave dwelling species have no eyes, or possess vestigial eyes incapable of sight.[citation needed]

Other senses

As with other arthropods, spiders' cuticles would block out information about the outside world, except that they are penetrated by many sensors or connections from sensors to the nervous system. In fact, spiders and other arthropods have modified their cuticles into elaborate arrays of sensors. Various touch sensors, mostly bristles called setae, respond to different levels of force, from strong contact to very weak air currents. Chemical sensors provide equivalents of taste and smell, often by means of setae.[25] An adult Araneus may have up to 1,000 such chemosensitive setae, most on the tarsi of the first pair of legs. Males have more chemosensitive bristles on their pedipalps than females. They have been shown to be responsive to sex pheromones produced by females, both contact and air-borne.[30] The jumping spider Evarcha culicivora uses the scent of blood from mammals and other vertebrates, which is obtained by capturing blood-filled mosquitoes, to attract the opposite sex. Because they are able to tell the sexes apart, it is assumed the blood scent is mixed with pheromones.[31] Spiders also have in the joints of their limbs slit sensillae that detect force and vibrations. In web-building spiders, all these mechanical and chemical sensors are more important than the eyes, while the eyes are most important to spiders that hunt actively.[13]

Like most arthropods, spiders lack balance and acceleration sensors and rely on their eyes to tell them which way is up. Arthropods' proprioceptors, sensors that report the force exerted by muscles and the degree of bending in the body and joints, are well-understood. On the other hand, little is known about what other internal sensors spiders or other arthropods may have.[25]

Some spiders use their webs for hearing, where the giant webs function as extended and reconfigurable auditory sensors.[32]

Locomotion

 
Image of a spider leg: 1–coxa; 2–trochanter; 3–femur; 4–patella; 5–tibia; 6–metatarsus; 7–tarsus; 8–claws

Each of the eight legs of a spider consists of seven distinct parts. The part closest to and attaching the leg to the cephalothorax is the coxa; the next segment is the short trochanter that works as a hinge for the following long segment, the femur; next is the spider's knee, the patella, which acts as the hinge for the tibia; the metatarsus is next, and it connects the tibia to the tarsus (which may be thought of as a foot of sorts); the tarsus ends in a claw made up of either two or three points, depending on the family to which the spider belongs. Although all arthropods use muscles attached to the inside of the exoskeleton to flex their limbs, spiders and a few other groups still use hydraulic pressure to extend them, a system inherited from their pre-arthropod ancestors.[33] The only extensor muscles in spider legs are located in the three hip joints (bordering the coxa and the trochanter).[34] As a result, a spider with a punctured cephalothorax cannot extend its legs, and the legs of dead spiders curl up.[13] Spiders can generate pressures up to eight times their resting level to extend their legs,[35] and jumping spiders can jump up to 50 times their own length by suddenly increasing the blood pressure in the third or fourth pair of legs.[13] Although larger spiders use hydraulics to straighten their legs, unlike smaller jumping spiders they depend on their flexor muscles to generate the propulsive force for their jumps.[34]

Most spiders that hunt actively, rather than relying on webs, have dense tufts of fine bristles between the paired claws at the tips of their legs. These tufts, known as scopulae, consist of bristles whose ends are split into as many as 1,000 branches, and enable spiders with scopulae to walk up vertical glass and upside down on ceilings. It appears that scopulae get their grip from contact with extremely thin layers of water on surfaces.[13] Spiders, like most other arachnids, keep at least four legs on the surface while walking or running.[36]

Silk production

Main article: Spider silk
 
An orb weaver producing silk from its spinnerets

The abdomen has no appendages except those that have been modified to form one to four (usually three) pairs of short, movable spinnerets, which emit silk. Each spinneret has many spigots, each of which is connected to one silk gland. There are at least six types of silk gland, each producing a different type of silk.[13] Spitting spiders also produce silk in modified venom glands.[37]

Silk is mainly composed of a protein very similar to that used in insect silk. It is initially a liquid, and hardens not by exposure to air but as a result of being drawn out, which changes the internal structure of the protein.[38] It is similar in tensile strength to nylon and biological materials such as chitin, collagen and cellulose, but is much more elastic. In other words, it can stretch much further before breaking or losing shape.[13]

Some spiders have a cribellum, a modified spinneret with up to 40,000 spigots, each of which produces a single very fine fiber. The fibers are pulled out by the calamistrum, a comblike set of bristles on the jointed tip of the cribellum, and combined into a composite woolly thread that is very effective in snagging the bristles of insects. The earliest spiders had cribella, which produced the first silk capable of capturing insects, before spiders developed silk coated with sticky droplets. However, most modern groups of spiders have lost the cribellum.[13]

Even species that do not build webs to catch prey use silk in several ways: as wrappers for sperm and for fertilized eggs; as a "safety rope"; for nest-building; and as "parachutes" by the young of some species.[13]

Reproduction and life cycle

Further information: Spider cannibalism
Mating behaviour of Neriene radiata

Spiders reproduce sexually and fertilization is internal but indirect, in other words the sperm is not inserted into the female's body by the male's genitals but by an intermediate stage. Unlike many land-living arthropods,[39] male spiders do not produce ready-made spermatophores (packages of sperm), but spin small sperm webs onto which they ejaculate and then transfer the sperm to special syringe-styled structures, palpal bulbs or palpal organs, borne on the tips of the pedipalps of mature males. When a male detects signs of a female nearby he checks whether she is of the same species and whether she is ready to mate; for example in species that produce webs or "safety ropes", the male can identify the species and sex of these objects by "smell".[13]

Spiders generally use elaborate courtship rituals to prevent the large females from eating the small males before fertilization, except where the male is so much smaller that he is not worth eating. In web-weaving species, precise patterns of vibrations in the web are a major part of the rituals, while patterns of touches on the female's body are important in many spiders that hunt actively, and may "hypnotize" the female. Gestures and dances by the male are important for jumping spiders, which have excellent eyesight. If courtship is successful, the male injects his sperm from the palpal bulbs into the female via one or two openings on the underside of her abdomen.[13]

Spider fertilization systems
 
Haplogyne or non-entelegyne
 
Entelegyne
Schematic diagrams showing sperm entering and being stored in the spermathecae; eggs leaving the ovaries and being fertilized; and finally a fertilized egg leaving the female's body

Female spiders' reproductive tracts are arranged in one of two ways. The ancestral arrangement ("haplogyne" or "non-entelegyne") consists of a single genital opening, leading to two seminal receptacles (spermathecae) in which females store sperm. In the more advanced arrangement ("entelegyne"), there are two further openings leading directly to the spermathecae, creating a "flow through" system rather than a "first-in first-out" one. Eggs are as a general rule only fertilized during oviposition when the stored sperm is released from its chamber, rather than in the ovarian cavity.[40] A few exceptions exist, such as Parasteatoda tepidariorum. In these species the female appears to be able to activate the dormant sperm before oviposition, allowing them to migrate to the ovarian cavity where fertilization occurs.[41][42][43] The only known example of direct fertilization between male and female is an Israeli spider, Harpactea sadistica, which has evolved traumatic insemination. In this species the male will penetrate its pedipalps through the female's body wall and inject his sperm directly into her ovaries, where the embryos inside the fertilized eggs will start to develop before being laid.[44]

Males of the genus Tidarren amputate one of their palps before maturation and enter adult life with one palp only. The palps are 20% of the male's body mass in this species, and detaching one of the two improves mobility. In the Yemeni species Tidarren argo, the remaining palp is then torn off by the female. The separated palp remains attached to the female's epigynum for about four hours and apparently continues to function independently. In the meantime, the female feeds on the palpless male.[45] In over 60% of cases, the female of the Australian redback spider kills and eats the male after it inserts its second palp into the female's genital opening; in fact, the males co-operate by trying to impale themselves on the females' fangs. Observation shows that most male redbacks never get an opportunity to mate, and the "lucky" ones increase the likely number of offspring by ensuring that the females are well-fed.[46] However, males of most species survive a few matings, limited mainly by their short life spans. Some even live for a while in their mates' webs.[47]

  •  
    The tiny male of the golden orb weaver (Trichonephila clavipes) (near the top of the leaf) is protected from the female by producing the right vibrations in the web, and may be too small to be worth eating.
  •  
    Orange spider egg sac hanging from ceiling
  •  
    Gasteracantha mammosa spiderlings next to their eggs capsule
  •  
    Wolf spider carrying its young on its abdomen

Females lay up to 3,000 eggs in one or more silk egg sacs,[13] which maintain a fairly constant humidity level.[47] In some species, the females die afterwards, but females of other species protect the sacs by attaching them to their webs, hiding them in nests, carrying them in the chelicerae or attaching them to the spinnerets and dragging them along.[13]

Baby spiders pass all their larval stages inside the egg sac and emerge as spiderlings, very small and sexually immature but similar in shape to adults. Some spiders care for their young, for example a wolf spider's brood clings to rough bristles on the mother's back,[13] and females of some species respond to the "begging" behaviour of their young by giving them their prey, provided it is no longer struggling, or even regurgitate food.[47]

Like other arthropods, spiders have to molt to grow as their cuticle ("skin") cannot stretch.[48] In some species males mate with newly molted females, which are too weak to be dangerous to the males.[47] Most spiders live for only one to two years, although some tarantulas can live in captivity for over 20 years,[13][49] and an Australian female trapdoor spider was documented to have lived in the wild for 43 years, dying of a parasitic wasp attack.[50]

Size

 
Goliath birdeater (Theraphosa blondi), the largest spider by mass

Spiders occur in a large range of sizes. The smallest, Patu digua from Colombia, are less than 0.37 mm (0.015 in) in body length. The largest and heaviest spiders occur among tarantulas, which can have body lengths up to 90 mm (3.5 in) and leg spans up to 250 mm (9.8 in).[51]

Coloration

Only three classes of pigment (ommochromes, bilins and guanine) have been identified in spiders, although other pigments have been detected but not yet characterized. Melanins, carotenoids and pterins, very common in other animals, are apparently absent. In some species, the exocuticle of the legs and prosoma is modified by a tanning process, resulting in a brown coloration.[52] Bilins are found, for example, in Micrommata virescens, resulting in its green color. Guanine is responsible for the white markings of the European garden spider Araneus diadematus. It is in many species accumulated in specialized cells called guanocytes. In genera such as Tetragnatha, Leucauge, Argyrodes or Theridiosoma, guanine creates their silvery appearance. While guanine is originally an end-product of protein metabolism, its excretion can be blocked in spiders, leading to an increase in its storage.[52] Structural colors occur in some species, which are the result of the diffraction, scattering or interference of light, for example by modified setae or scales. The white prosoma of Argiope results from bristles reflecting the light, Lycosa and Josa both have areas of modified cuticle that act as light reflectors.[52] The peacock spiders of Australia (genus Maratus) are notable for their bright structural colours in the males.

While in many spiders color is fixed throughout their lifespan, in some groups, color may be variable in response to environmental and internal conditions.[52] Choice of prey may be able to alter the color of spiders. For example, the abdomen of Theridion grallator will become orange if the spider ingests certain species of Diptera and adult Lepidoptera, but if it consumes Homoptera or larval Lepidoptera, then the abdomen becomes green.[53] Environmentally induced color changes may be morphological (occurring over several days) or physiological (occurring near instantly). Morphological changes require pigment synthesis and degradation. In contrast to this, physiological changes occur by changing the position of pigment-containing cells.[52] An example of morphological color changes is background matching. Misumena vatia for instance can change its body color to match the substrate it lives on which makes it more difficult to be detected by prey.[54] An example of physiological color change is observed in Cyrtophora cicatrosa, which can change its body color from white to brown near instantly.[52]

Ecology and behavior

Non-predatory feeding

 
A jumping spider seen in Chennai.

Although spiders are generally regarded as predatory, the jumping spider Bagheera kiplingi gets over 90% of its food from fairly solid plant material, which acacias produce as part of a mutually beneficial relationship with a species of ant.[55]

Juveniles of some spiders in the families Anyphaenidae, Corinnidae, Clubionidae, Thomisidae and Salticidae feed on plant nectar. Laboratory studies show that they do so deliberately and over extended periods, and periodically clean themselves while feeding. These spiders also prefer sugar solutions to plain water, which indicates that they are seeking nutrients. Since many spiders are nocturnal, the extent of nectar consumption by spiders may have been underestimated. Nectar contains amino acids, lipids, vitamins and minerals in addition to sugars, and studies have shown that other spider species live longer when nectar is available. Feeding on nectar avoids the risks of struggles with prey, and the costs of producing venom and digestive enzymes.[56]

Various species are known to feed on dead arthropods (scavenging), web silk, and their own shed exoskeletons. Pollen caught in webs may also be eaten, and studies have shown that young spiders have a better chance of survival if they have the opportunity to eat pollen. In captivity, several spider species are also known to feed on bananas, marmalade, milk, egg yolk and sausages.[56]

Capturing prey

Main article: Spider web
 
Crab spider with prey
 
The Phonognatha graeffei or leaf-curling spider's web serves both as a trap and as a way of making its home in a leaf.

The best-known method of prey capture is by means of sticky webs. Varying placement of webs allows different species of spider to trap different insects in the same area, for example flat horizontal webs trap insects that fly up from vegetation underneath while flat vertical webs trap insects in horizontal flight. Web-building spiders have poor vision, but are extremely sensitive to vibrations.[13]

Females of the water spider Argyroneta aquatica build underwater "diving bell" webs that they fill with air and use for digesting prey, molting, mating and raising offspring. They live almost entirely within the bells, darting out to catch prey animals that touch the bell or the threads that anchor it.[57] A few spiders use the surfaces of lakes and ponds as "webs", detecting trapped insects by the vibrations that these cause while struggling.[13]

Net-casting spiders weave only small webs, but then manipulate them to trap prey. Those of the genus Hyptiotes and the family Theridiosomatidae stretch their webs and then release them when prey strike them, but do not actively move their webs. Those of the family Deinopidae weave even smaller webs, hold them outstretched between their first two pairs of legs, and lunge and push the webs as much as twice their own body length to trap prey, and this move may increase the webs' area by a factor of up to ten. Experiments have shown that Deinopis spinosus has two different techniques for trapping prey: backwards strikes to catch flying insects, whose vibrations it detects; and forward strikes to catch ground-walking prey that it sees. These two techniques have also been observed in other deinopids. Walking insects form most of the prey of most deinopids, but one population of Deinopis subrufa appears to live mainly on tipulid flies that they catch with the backwards strike.[58]

Mature female bolas spiders of the genus Mastophora build "webs" that consist of only a single "trapeze line", which they patrol. They also construct a bolas made of a single thread, tipped with a large ball of very wet sticky silk. They emit chemicals that resemble the pheromones of moths, and then swing the bolas at the moths. Although they miss on about 50% of strikes, they catch about the same weight of insects per night as web-weaving spiders of similar size. The spiders eat the bolas if they have not made a kill in about 30 minutes, rest for a while, and then make new bolas.[59][60] Juveniles and adult males are much smaller and do not make bolas. Instead they release different pheromones that attract moth flies, and catch them with their front pairs of legs.[61]

 
A trapdoor spider in the genus Cyclocosmia, an ambush predator

The primitive Liphistiidae, the "trapdoor spiders" of the family Ctenizidae and many tarantulas are ambush predators that lurk in burrows, often closed by trapdoors and often surrounded by networks of silk threads that alert these spiders to the presence of prey.[17] Other ambush predators do without such aids, including many crab spiders,[13] and a few species that prey on bees, which see ultraviolet, can adjust their ultraviolet reflectance to match the flowers in which they are lurking.[52] Wolf spiders, jumping spiders, fishing spiders and some crab spiders capture prey by chasing it, and rely mainly on vision to locate prey.[13]

 
Portia uses both webs and cunning, versatile tactics to overcome prey.[62]

Some jumping spiders of the genus Portia hunt other spiders in ways that seem intelligent,[22] outflanking their victims or luring them from their webs. Laboratory studies show that Portia's instinctive tactics are only starting points for a trial-and-error approach from which these spiders learn very quickly how to overcome new prey species.[62] However, they seem to be relatively slow "thinkers", which is not surprising, as their brains are vastly smaller than those of mammalian predators.[22]

 
An ant-mimicking jumping spider

Ant-mimicking spiders face several challenges: they generally develop slimmer abdomens and false "waists" in the cephalothorax to mimic the three distinct regions (tagmata) of an ant's body; they wave the first pair of legs in front of their heads to mimic antennae, which spiders lack, and to conceal the fact that they have eight legs rather than six; they develop large color patches round one pair of eyes to disguise the fact that they generally have eight simple eyes, while ants have two compound eyes; they cover their bodies with reflective bristles to resemble the shiny bodies of ants. In some spider species, males and females mimic different ant species, as female spiders are usually much larger than males. Ant-mimicking spiders also modify their behavior to resemble that of the target species of ant; for example, many adopt a zig-zag pattern of movement, ant-mimicking jumping spiders avoid jumping, and spiders of the genus Synemosyna walk on the outer edges of leaves in the same way as Pseudomyrmex. Ant mimicry in many spiders and other arthropods may be for protection from predators that hunt by sight, including birds, lizards and spiders. However, several ant-mimicking spiders prey either on ants or on the ants' "livestock", such as aphids. When at rest, the ant-mimicking crab spider Amyciaea does not closely resemble Oecophylla, but while hunting it imitates the behavior of a dying ant to attract worker ants. After a kill, some ant-mimicking spiders hold their victims between themselves and large groups of ants to avoid being attacked.[63]

Defense

 
Threat display by a Sydney funnel-web spider (Atrax robustus).

There is strong evidence that spiders' coloration is camouflage that helps them to evade their major predators, birds and parasitic wasps, both of which have good color vision. Many spider species are colored so as to merge with their most common backgrounds, and some have disruptive coloration, stripes and blotches that break up their outlines. In a few species, such as the Hawaiian happy-face spider, Theridion grallator, several coloration schemes are present in a ratio that appears to remain constant, and this may make it more difficult for predators to recognize the species. Most spiders are insufficiently dangerous or unpleasant-tasting for warning coloration to offer much benefit. However, a few species with powerful venom, large jaws or irritant bristles have patches of warning colors, and some actively display these colors when threatened.[52][64]

Many of the family Theraphosidae, which includes tarantulas and baboon spiders, have urticating hairs on their abdomens and use their legs to flick them at attackers. These bristles are fine setae (bristles) with fragile bases and a row of barbs on the tip. The barbs cause intense irritation but there is no evidence that they carry any kind of venom.[65] A few defend themselves against wasps by including networks of very robust threads in their webs, giving the spider time to flee while the wasps are struggling with the obstacles.[66] The golden wheeling spider, Carparachne aureoflava, of the Namibian desert escapes parasitic wasps by flipping onto its side and cartwheeling down sand dunes.[67]

Socialization

Main article: Social spider

A few spider species that build webs live together in large colonies and show social behavior, although not as complex as in social insects. Anelosimus eximius (in the family Theridiidae) can form colonies of up to 50,000 individuals.[68] The genus Anelosimus has a strong tendency towards sociality: all known American species are social, and species in Madagascar are at least somewhat social.[69] Members of other species in the same family but several different genera have independently developed social behavior. For example, although Theridion nigroannulatum belongs to a genus with no other social species, T. nigroannulatum build colonies that may contain several thousand individuals that co-operate in prey capture and share food.[70] Other communal spiders include several Philoponella species (family Uloboridae), Agelena consociata (family Agelenidae) and Mallos gregalis (family Dictynidae).[71] Social predatory spiders need to defend their prey against kleptoparasites ("thieves"), and larger colonies are more successful in this.[72] The herbivorous spider Bagheera kiplingi lives in small colonies which help to protect eggs and spiderlings.[55] Even widow spiders (genus Latrodectus), which are notoriously cannibalistic, have formed small colonies in captivity, sharing webs and feeding together.[73]

In experiments, spider species like Steatoda grossa, Latrodectus hesperus and Eratigena agrestis stayed away from Myrmica rubra ant colonies. These ants are predators and the pheromones they release for communication have a notable deterrent effect on these spider species.[74]

Web types

Main article: Spider web
 
The large orb web of Araneus diadematus (European garden spider).

There is no consistent relationship between the classification of spiders and the types of web they build: species in the same genus may build very similar or significantly different webs. Nor is there much correspondence between spiders' classification and the chemical composition of their silks. Convergent evolution in web construction, in other words use of similar techniques by remotely related species, is rampant. Orb web designs and the spinning behaviors that produce them are the best understood. The basic radial-then-spiral sequence visible in orb webs and the sense of direction required to build them may have been inherited from the common ancestors of most spider groups.[75] However, the majority of spiders build non-orb webs. It used to be thought that the sticky orb web was an evolutionary innovation resulting in the diversification of the Orbiculariae. Now, however, it appears that non-orb spiders are a subgroup that evolved from orb-web spiders, and non-orb spiders have over 40% more species and are four times as abundant as orb-web spiders. Their greater success may be because sphecid wasps, which are often the dominant predators of spiders, much prefer to attack spiders that have flat webs.[76]

Orb

 
Nephila clavata, a golden orb weaver

About half the potential prey that hit orb webs escape. A web has to perform three functions: intercepting the prey (intersection), absorbing its momentum without breaking (stopping), and trapping the prey by entangling it or sticking to it (retention). No single design is best for all prey. For example: wider spacing of lines will increase the web's area and hence its ability to intercept prey, but reduce its stopping power and retention; closer spacing, larger sticky droplets and thicker lines would improve retention, but would make it easier for potential prey to see and avoid the web, at least during the day. However, there are no consistent differences between orb webs built for use during the day and those built for use at night. In fact, there is no simple relationship between orb web design features and the prey they capture, as each orb-weaving species takes a wide range of prey.[75]

The hubs of orb webs, where the spiders lurk, are usually above the center, as the spiders can move downwards faster than upwards. If there is an obvious direction in which the spider can retreat to avoid its own predators, the hub is usually offset towards that direction.[75]

Horizontal orb webs are fairly common, despite being less effective at intercepting and retaining prey and more vulnerable to damage by rain and falling debris. Various researchers have suggested that horizontal webs offer compensating advantages, such as reduced vulnerability to wind damage; reduced visibility to prey flying upwards, because of the backlighting from the sky; enabling oscillations to catch insects in slow horizontal flight. However, there is no single explanation for the common use of horizontal orb webs.[75]

Spiders often attach highly visible silk bands, called decorations or stabilimenta, to their webs. Field research suggests that webs with more decorative bands captured more prey per hour.[77] However, a laboratory study showed that spiders reduce the building of these decorations if they sense the presence of predators.[78]

There are several unusual variants of orb web, many of them convergently evolved, including: attachment of lines to the surface of water, possibly to trap insects in or on the surface; webs with twigs through their centers, possibly to hide the spiders from predators; "ladderlike" webs that appear most effective in catching moths. However, the significance of many variations is unclear.[75] The orb-weaving species, Zygiella x-notata, for example, is known for its characteristic missing sector orb web. The missing sector contains a signal thread used to detect prey vibrations on the female's web.[79]

In 1973, Skylab 3 took two orb-web spiders into space to test their web-spinning capabilities in zero gravity. At first, both produced rather sloppy webs, but they adapted quickly.[80]

Cobweb

 
A funnel web.

Members of the family Theridiidae weave irregular, tangled, three-dimensional webs, popularly known as cobwebs. There seems to be an evolutionary trend towards a reduction in the amount of sticky silk used, leading to its total absence in some species. The construction of cobwebs is less stereotyped than that of orb-webs, and may take several days.[76]

Other

The Linyphiidae generally make horizontal but uneven sheets, with tangles of stopping threads above. Insects that hit the stopping threads fall onto the sheet or are shaken onto it by the spider, and are held by sticky threads on the sheet until the spider can attack from below.[81]

Web design in zero gravity

Many experiments have been conducted to study the effect of zero gravity on the design of spider webs. In late 2020, reports of recent experiments were published that indicated that although web design was affected adversely in zero gravity conditions, having access to a light source could orient spiders and enable them to build their normally shaped webs under such conditions.[82][83]

Evolution

Main article: Spider evolution

Fossil record

 
Spider preserved in amber

Although the fossil record of spiders is considered poor,[84] almost 1000 species have been described from fossils.[85] Because spiders' bodies are quite soft, the vast majority of fossil spiders have been found preserved in amber.[85] The oldest known amber that contains fossil arthropods dates from 130 million years ago in the Early Cretaceous period. In addition to preserving spiders' anatomy in very fine detail, pieces of amber show spiders mating, killing prey, producing silk and possibly caring for their young. In a few cases, amber has preserved spiders' egg sacs and webs, occasionally with prey attached;[86] the oldest fossil web found so far is 100 million years old.[87] Earlier spider fossils come from a few lagerstätten, places where conditions were exceptionally suited to preserving fairly soft tissues.[86]

The oldest known exclusively terrestrial arachnid is the trigonotarbid Palaeotarbus jerami, from about 420 million years ago in the Silurian period, and had a triangular cephalothorax and segmented abdomen, as well as eight legs and a pair of pedipalps.[88] Attercopus fimbriunguis, from 386 million years ago in the Devonian period, bears the earliest known silk-producing spigots, and was therefore hailed as a spider at the time of its discovery.[89] However, these spigots may have been mounted on the underside of the abdomen rather than on spinnerets, which are modified appendages and whose mobility is important in the building of webs. Hence Attercopus and the similar Permian arachnid Permarachne may not have been true spiders, and probably used silk for lining nests or producing egg cases rather than for building webs.[3] The largest known fossil spider as of 2011 is the araneid Nephila jurassica, from about 165 million years ago, recorded from Daohuogo, Inner Mongolia in China.[90] Its body length is almost 25 mm, (i.e., almost one inch).

Several Carboniferous spiders were members of the Mesothelae, a primitive group now represented only by the Liphistiidae.[89] The mesothelid Paleothele montceauensis, from the Late Carboniferous over 299 million years ago, had five spinnerets.[91] Although the Permian period 299 to 251 million years ago saw rapid diversification of flying insects, there are very few fossil spiders from this period.[89]

The main groups of modern spiders, Mygalomorphae and Araneomorphae, first appear in the Triassic well before 200 million years ago. Some Triassic mygalomorphs appear to be members of the family Hexathelidae, whose modern members include the notorious Sydney funnel-web spider, and their spinnerets appear adapted for building funnel-shaped webs to catch jumping insects. Araneomorphae account for the great majority of modern spiders, including those that weave the familiar orb-shaped webs. The Jurassic and Cretaceous periods provide a large number of fossil spiders, including representatives of many modern families.[89]

According to a 2020 study using a molecular clock calibrated with 27 chelicerate fossils, spiders most likely diverged from other chelicerates between 375 and 328 million years ago.[92]

External relationships

The spiders (Araneae) are monophyletic (i.e., a clade, consisting of a last common ancestor and all of its descendants).[93] There has been debate about what their closest evolutionary relatives are, and how all of these evolved from the ancestral chelicerates, which were marine animals.[93] This 2019 cladogram illustrates the spiders' phylogenetic relationships.[94][95]

Arachnids lack some features of other chelicerates, including backward-pointing mouths and gnathobases ("jaw bases") at the bases of their legs;[93] both of these features are part of the ancestral arthropod feeding system.[96] Instead, they have mouths that point forwards and downwards, and all have some means of breathing air.[93] Spiders (Araneae) are distinguished from other arachnid groups by several characteristics, including spinnerets and, in males, pedipalps that are specially adapted for sperm transfer.[97]

Chelicerata

Pycnogonida (sea spiders)  

Prosomapoda

Xiphosura (horseshoe crabs)  

Eurypterida (sea scorpions)  

Arachnida
Non‑pulmonates

(ticks, harvestmen, etc)  

pulmonates
Scorpiones

 

Tetrapulmonata

Araneae (spiders)  

Pedipalpi (whip scorpions, etc)  

Internal relationships

The cladogram shows the relation among spider suborders and families:[98]

Taxonomy

Main article: Spider taxonomy

The order name Araneae derives from Latin aranea[99] borrowing Ancient Greek ἀράχνη arákhnē from ἀράχνης arákhnēs.[100]

Spiders are divided into two suborders, Mesothelae and Opisthothelae, of which the latter contains two infraorders, Mygalomorphae and Araneomorphae. Some 50,356 living species of spiders (order Araneae) have been identified, grouped into 132 families and 4,280 genera by arachnologists in 2022.[1]

  Spider diversity[1][97][5]
(numbers are approximate)		 Features
Suborder/Infraorder Families Genera Species Segmented plates on top of abdomen[101] Ganglia in abdomen Spinnerets[101] Striking direction of fangs[13]
Mesothelae 2 8 169 Yes Yes Four pairs, in some species one pair fused, under middle of abdomen Downwards and forwards
Opisthothelae: Mygalomorphae 31 368 3,327 Only in some fossils No One, two or three pairs under rear of abdomen
Opisthothelae: Araneomorphae 99 3,899 46,770 From sides to center, like pincers

Mesothelae

Main article: Mesothelae
 
Ryuthela sasakii, a member of the Liphistiidae[102]

The only living members of the primitive Mesothelae are the family Liphistiidae, found only in Southeast Asia, China, and Japan.[97] Most of the Liphistiidae construct silk-lined burrows with thin trapdoors, although some species of the genus Liphistius build camouflaged silk tubes with a second trapdoor as an emergency exit. Members of the genus Liphistius run silk "tripwires" outwards from their tunnels to help them detect approaching prey, while those of the genus Heptathela do not and instead rely on their built-in vibration sensors.[103] Spiders of the genus Heptathela have no venom glands, although they do have venom gland outlets on the fang tip.[104]

The extinct families Arthrolycosidae, found in Carboniferous and Permian rocks, and Arthromygalidae, so far found only in Carboniferous rocks, have been classified as members of the Mesothelae.[105]

Mygalomorphae

Main article: Mygalomorphae
 
A Mexican red-kneed tarantula Brachypelma hamorii

The Mygalomorphae, which first appeared in the Triassic period,[89] are generally heavily built and ″hairy″, with large, robust chelicerae and fangs (technically, spiders do not have true hairs, but rather setae).[106][97] Well-known examples include tarantulas, ctenizid trapdoor spiders and the Australasian funnel-web spiders.[13] Most spend the majority of their time in burrows, and some run silk tripwires out from these, but a few build webs to capture prey. However, mygalomorphs cannot produce the pirifom silk that the Araneomorphae use as an instant adhesive to glue silk to surfaces or to other strands of silk, and this makes web construction more difficult for mygalomorphs. Since mygalomorphs rarely "balloon" by using air currents for transport, their populations often form clumps.[97] In addition to arthropods, some mygalomorphs are known to prey on frogs, small mammals, lizards, snakes, snails, and small birds.[107][108]

Araneomorphae

Main article: Araneomorphae
 
Leucauge venusta, an orb-web spider

In addition to accounting for over 90% of spider species, the Araneomorphae, also known as the "true spiders", include orb-web spiders, the cursorial wolf spiders, and jumping spiders,[97] as well as the only known herbivorous spider, Bagheera kiplingi.[55] They are distinguished by having fangs that oppose each other and cross in a pinching action, in contrast to the Mygalomorphae, which have fangs that are nearly parallel in alignment.[109]

Human interaction

Media coverage and misconceptions

Information about spiders in the media is often emphasizing how dangerous and unpleasant they are. A recent study investigated the global spread of (mis-)information on spiders using a high-resolution global database of online newspaper articles on spider–human interactions. These reports covered stories of spider–human encounters and bites published from 2010 to 2020. The study found that 47% of articles contained errors and 43% were sensationalist.[110]

Bites

Main article: Spider bite

Although spiders are widely feared, only a few species are dangerous to people.[111] Spiders will only bite humans in self-defense, and few produce worse effects than a mosquito bite or bee sting.[112] Most of those with medically serious bites, such as recluse spiders (genus Loxosceles) and widow spiders (genus Latrodectus), would rather flee and bite only when trapped, although this can easily arise by accident.[113][114] The defensive tactics of Australian funnel-web spiders (family Atracidae) include fang display. Their venom, although they rarely inject much, has resulted in 13 attributed human deaths over 50 years.[115] They have been deemed to be the world's most dangerous spiders on clinical and venom toxicity grounds,[111] though this claim has also been attributed to the Brazilian wandering spider (genus Phoneutria).[116]

There were about 100 reliably reported deaths from spider bites in the 20th century,[117] compared to about 1,500 from jellyfish stings.[118] Many alleged cases of spider bites may represent incorrect diagnoses,[119] which would make it more difficult to check the effectiveness of treatments for genuine bites.[120] A review published in 2016 agreed with this conclusion, showing that 78% of 134 published medical case studies of supposed spider bites did not meet the necessary criteria for a spider bite to be verified. In the case of the two genera with the highest reported number of bites, Loxosceles and Latrodectus, spider bites were not verified in over 90% of the reports. Even when verification had occurred, details of the treatment and its effects were often lacking.[121]

Silk

Main article: Spider silk

Because spider silk is both light and very strong, attempts are being made to produce it in goats' milk and in the leaves of plants, by means of genetic engineering.[122][123]

Arachnophobia

Main article: Arachnophobia

Arachnophobia is a specific phobia—it is the abnormal fear of spiders or anything reminiscent of spiders, such as webs or spiderlike shapes. It is one of the most common specific phobias,[124][125] and some statistics show that 50% of women and 10% of men show symptoms.[126] It may be an exaggerated form of an instinctive response that helped early humans to survive,[127] or a cultural phenomenon that is most common in predominantly European societies.[128]

As food

See also: Fried spider
 
Cooked tarantulas are considered a delicacy in Cambodia.

Spiders are used as food.[129] Cooked tarantulas are considered a delicacy in Cambodia,[130] and by the Piaroa Indians of southern Venezuela – provided the highly irritant bristles, the spiders' main defense system, are removed first.[131]

Spiders in culture

Main article: Cultural depictions of spiders
 
This Moche ceramic depicts a spider, and dates from around 300 CE.

Spiders have been the focus of stories and mythologies of various cultures for centuries.[132] Uttu, the ancient Sumerian goddess of weaving, was envisioned as a spider spinning her web.[133][134] According to her main myth, she resisted her father Enki's sexual advances by ensconcing herself in her web,[134] but let him in after he promised her fresh produce as a marriage gift,[134] thereby allowing him to intoxicate her with beer and rape her.[134] Enki's wife Ninhursag heard Uttu's screams and rescued her,[134] removing Enki's semen from her vagina and planting it in the ground to produce eight previously nonexistent plants.[134]

In a story told by the Roman poet Ovid in his Metamorphoses, Arachne (Ancient Greek for "spider") was a Lydian girl who challenged the goddess Athena to a weaving contest.[135][136] Arachne won, but Athena destroyed her tapestry out of jealousy,[136][137] causing Arachne to hang herself.[136][137] In an act of mercy, Athena brought Arachne back to life as the first spider.[136][137] Stories about the trickster-spider Anansi are prominent in the folktales of West Africa and the Caribbean.[138]

In some cultures, spiders have symbolized patience due to their hunting technique of setting webs and waiting for prey, as well as mischief and malice due to their venomous bites.[139] The Italian tarantella is a dance to rid the young woman of the lustful effects of a spider bite. Web-spinning also caused the association of the spider with creation myths, as they seem to have the ability to produce their own worlds.[140] Dreamcatchers are depictions of spiderwebs. The Moche people of ancient Peru worshipped nature.[141] They placed emphasis on animals and often depicted spiders in their art.[142]

See also

Citations

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General and cited references

  • Deeleman-Reinhold, Christa L. (2001). Forest Spiders of South East Asia: With a Revision of the Sac and Ground Spiders. Brill Publishers. ISBN 978-9004119598.
  • Ruppert, E.E.; Fox, R.S.; Barnes, R.D. (2004). Invertebrate Zoology (7th ed.). Brooks/Cole. ISBN 978-0-03-025982-1.

Further reading

  • Bilger, Burkhard (5 March 2007). "Spider Woman". The New Yorker. pp. 66–73.
  • Bristowe, W. S. (1976). The World of Spiders. Taplinger Publishing Company. ISBN 978-0-8008-8598-4. OCLC 256272177.
  • Crompton, John (1950). The Life of the Spider. New York: Mentor. OCLC 1979220.
  • Hillyard, Paul (1994). The Book of the Spider: From Arachnophobia to the Love of Spiders. New York: Random House. ISBN 978-0-679-40881-9. OCLC 35231232.
  • Kaston, B. J.; Kaston, Elizabeth (1953). How to Know the Spiders: Pictured-Keys for Determining the More Common Spiders, with Suggestions for Collecting and Studying Them (1st ed.). Dubuque, Iowa: W.C. Brown Company. OCLC 628203833.
  • Main, Barbara York (1975). Spiders. Sydney: Collins. ISBN 978-0-00-211443-1. OCLC 123151744.
  • Wise, David A. (1993). Spiders in Ecological Webs. Cambridge Studies in Ecology. Cambridge: Cambridge University Press. ISBN 978-0-521-32547-9. OCLC 25833874.

External links

  • Spiders at Curlie
  • Picture story about the jumping spider Aelurillus v-insignitus
  • New Mexico State University "The Spiders of the Arid Southwest"
  • Online Videos of Jumping Spiders (Salticids) and other arachnids
  • , from the International Field Guides database
  • Spider hunts on YouTube
  • Record breaking achievements by spiders and the scientists who study them

January 11, 2024
spider, other, uses, disambiguation, order, araneae, breathing, arthropods, that, have, eight, limbs, chelicerae, with, fangs, generally, able, inject, venom, spinnerets, that, extrude, silk, they, largest, order, arachnids, rank, seventh, total, species, dive. For other uses see Spider disambiguation Spiders order Araneae are air breathing arthropods that have eight limbs chelicerae with fangs generally able to inject venom 2 and spinnerets that extrude silk 3 They are the largest order of arachnids and rank seventh in total species diversity among all orders of organisms 4 5 Spiders are found worldwide on every continent except for Antarctica and have become established in nearly every land habitat As of November 2023 update 51 673 spider species in 136 families have been recorded by taxonomists 1 However there has been debate among scientists about how families should be classified with over 20 different classifications proposed since 1900 6 SpidersTemporal range Pennsylvanian Holocene 319 0 Ma PreꞒ Ꞓ O S D C P T J K Pg NAn assortment of different spidersScientific classificationDomain EukaryotaKingdom AnimaliaPhylum ArthropodaSubphylum ChelicerataClass ArachnidaClade TetrapulmonataOrder AraneaeClerck 1757SubordersMesothelae Opisthothelae Mygalomorphae Araneomorphae See Spider taxonomy Diversity 1 132 families c 50 000 speciesAnatomically spiders as with all arachnids differ from other arthropods in that the usual body segments are fused into two tagmata the cephalothorax or prosoma and the opisthosoma or abdomen and joined by a small cylindrical pedicel However as there is currently neither paleontological nor embryological evidence that spiders ever had a separate thorax like division there exists an argument against the validity of the term cephalothorax which means fused cephalon head and the thorax Similarly arguments can be formed against use of the term abdomen as the opisthosoma of all spiders contains a heart and respiratory organs organs atypical of an abdomen 7 Unlike insects spiders do not have antennae In all except the most primitive group the Mesothelae spiders have the most centralized nervous systems of all arthropods as all their ganglia are fused into one mass in the cephalothorax Unlike most arthropods spiders have no extensor muscles in their limbs and instead extend them by hydraulic pressure Their abdomens bear appendages that have been modified into spinnerets that extrude silk from up to six types of glands Spider webs vary widely in size shape and the amount of sticky thread used It now appears that the spiral orb web may be one of the earliest forms and spiders that produce tangled cobwebs are more abundant and diverse than orb weaver spiders Spider like arachnids with silk producing spigots Uraraneida appeared in the Devonian period about 386 million years ago but these animals apparently lacked spinnerets True spiders have been found in Carboniferous rocks from 318 to 299 million years ago and are very similar to the most primitive surviving suborder the Mesothelae The main groups of modern spiders Mygalomorphae and Araneomorphae first appeared in the Triassic period before 200 million years ago The species Bagheera kiplingi was described as herbivorous in 2008 8 but all other known species are predators mostly preying on insects and on other spiders although a few large species also take birds and lizards It is estimated that the world s 25 million tons of spiders kill 400 800 million tons of prey per year 9 Spiders use a wide range of strategies to capture prey trapping it in sticky webs lassoing it with sticky bolas mimicking the prey to avoid detection or running it down Most detect prey mainly by sensing vibrations but the active hunters have acute vision and hunters of the genus Portia show signs of intelligence in their choice of tactics and ability to develop new ones Spiders guts are too narrow to take solids so they liquefy their food by flooding it with digestive enzymes They also grind food with the bases of their pedipalps as arachnids do not have the mandibles that crustaceans and insects have To avoid being eaten by the females which are typically much larger male spiders identify themselves to potential mates by a variety of complex courtship rituals Males of most species survive a few matings limited mainly by their short life spans Females weave silk egg cases each of which may contain hundreds of eggs Females of many species care for their young for example by carrying them around or by sharing food with them A minority of species are social building communal webs that may house anywhere from a few to 50 000 individuals Social behavior ranges from precarious toleration as in the widow spiders to co operative hunting and food sharing Although most spiders live for at most two years tarantulas and other mygalomorph spiders can live up to 25 years in captivity While the venom of a few species is dangerous to humans scientists are now researching the use of spider venom in medicine and as non polluting pesticides Spider silk provides a combination of lightness strength and elasticity that is superior to that of synthetic materials and spider silk genes have been inserted into mammals and plants to see if these can be used as silk factories As a result of their wide range of behaviors spiders have become common symbols in art and mythology symbolizing various combinations of patience cruelty and creative powers An irrational fear of spiders is called arachnophobia Contents 1 Etymology 2 Description 2 1 Body plan 2 2 Circulation and respiration 2 3 Feeding digestion and excretion 2 4 Central nervous system 2 5 Sense organs 2 5 1 Eyes 2 5 2 Other senses 2 6 Locomotion 2 7 Silk production 2 8 Reproduction and life cycle 2 9 Size 2 10 Coloration 3 Ecology and behavior 3 1 Non predatory feeding 3 2 Capturing prey 3 3 Defense 3 4 Socialization 4 Web types 4 1 Orb 4 2 Cobweb 4 3 Other 4 4 Web design in zero gravity 5 Evolution 5 1 Fossil record 5 2 External relationships 5 3 Internal relationships 6 Taxonomy 6 1 Mesothelae 6 2 Mygalomorphae 6 3 Araneomorphae 7 Human interaction 7 1 Media coverage and misconceptions 7 2 Bites 7 3 Silk 7 4 Arachnophobia 7 5 As food 8 Spiders in culture 9 See also 10 Citations 11 General and cited references 12 Further reading 13 External linksEtymologyThe word spider derives from Proto Germanic spin thron literally spinner a reference to how spiders make their webs from the Proto Indo European root s pen to draw stretch spin 10 DescriptionMain article Spider anatomy Body plan nbsp Palystes castaneus female dorsal aspect pedipalptrichobothriacarapace of prosoma cephalothorax opisthosoma abdomen eyesAL anterior lateral AM anterior median PL posterior lateral PM posterior median Leg segments coxatrochanterfemurpatellatibiametatarsustarsusclawchelicera nbsp Palystes castaneus female ventral aspect Nos 1 to 14 as for dorsal aspect sternum of prosomapedicel also called pedicle book lung sacbook lung stigmaepigastric foldepigyneanterior spinneretposterior spinneret Legs are labelled I II III IV from anterior to posterior Spiders are chelicerates and therefore arthropods 11 As arthropods they have segmented bodies with jointed limbs all covered in a cuticle made of chitin and proteins heads that are composed of several segments that fuse during the development of the embryo 12 Being chelicerates their bodies consist of two tagmata sets of segments that serve similar functions the foremost one called the cephalothorax or prosoma is a complete fusion of the segments that in an insect would form two separate tagmata the head and thorax the rear tagma is called the abdomen or opisthosoma 11 In spiders the cephalothorax and abdomen are connected by a small cylindrical section the pedicel 13 The pattern of segment fusion that forms chelicerates heads is unique among arthropods and what would normally be the first head segment disappears at an early stage of development so that chelicerates lack the antennae typical of most arthropods In fact chelicerates only appendages ahead of the mouth are a pair of chelicerae and they lack anything that would function directly as jaws 12 14 The first appendages behind the mouth are called pedipalps and serve different functions within different groups of chelicerates 11 Spiders and scorpions are members of one chelicerate group the arachnids 14 Scorpions chelicerae have three sections and are used in feeding 15 Spiders chelicerae have two sections and terminate in fangs that are generally venomous and fold away behind the upper sections while not in use The upper sections generally have thick beards that filter solid lumps out of their food as spiders can take only liquid food 13 Scorpions pedipalps generally form large claws for capturing prey 15 while those of spiders are fairly small appendages whose bases also act as an extension of the mouth in addition those of male spiders have enlarged last sections used for sperm transfer 13 In spiders the cephalothorax and abdomen are joined by a small cylindrical pedicel which enables the abdomen to move independently when producing silk The upper surface of the cephalothorax is covered by a single convex carapace while the underside is covered by two rather flat plates The abdomen is soft and egg shaped It shows no sign of segmentation except that the primitive Mesothelae whose living members are the Liphistiidae have segmented plates on the upper surface 13 Circulation and respiration nbsp Like other arthropods spiders are coelomates in which the coelom is reduced to small areas around the reproductive and excretory systems Its place is largely taken by a hemocoel a cavity that runs most of the length of the body and through which blood flows The heart is a tube in the upper part of the body with a few ostia that act as non return valves allowing blood to enter the heart from the hemocoel but prevent it from leaving before it reaches the front end 16 However in spiders it occupies only the upper part of the abdomen and blood is discharged into the hemocoel by one artery that opens at the rear end of the abdomen and by branching arteries that pass through the pedicle and open into several parts of the cephalothorax Hence spiders have open circulatory systems 13 The blood of many spiders that have book lungs contains the respiratory pigment hemocyanin to make oxygen transport more efficient 14 Spiders have developed several different respiratory anatomies based on book lungs a tracheal system or both Mygalomorph and Mesothelae spiders have two pairs of book lungs filled with haemolymph where openings on the ventral surface of the abdomen allow air to enter and diffuse oxygen This is also the case for some basal araneomorph spiders like the family Hypochilidae but the remaining members of this group have just the anterior pair of book lungs intact while the posterior pair of breathing organs are partly or fully modified into tracheae through which oxygen is diffused into the haemolymph or directly to the tissue and organs 13 The tracheal system has most likely evolved in small ancestors to help resist desiccation 14 The trachea were originally connected to the surroundings through a pair of openings called spiracles but in the majority of spiders this pair of spiracles has fused into a single one in the middle and moved backwards close to the spinnerets 13 Spiders that have tracheae generally have higher metabolic rates and better water conservation 17 Spiders are ectotherms so environmental temperatures affect their activity 18 Feeding digestion and excretion nbsp A syrphid fly captured in the web of a spider nbsp Cheiracanthium punctorium displaying fangsUniquely among chelicerates the final sections of spiders chelicerae are fangs and the great majority of spiders can use them to inject venom into prey from venom glands in the roots of the chelicerae 13 The families Uloboridae and Holarchaeidae and some Liphistiidae spiders have lost their venom glands and kill their prey with silk instead 19 Like most arachnids including scorpions 14 spiders have a narrow gut that can only cope with liquid food and two sets of filters to keep solids out 13 They use one of two different systems of external digestion Some pump digestive enzymes from the midgut into the prey and then suck the liquified tissues of the prey into the gut eventually leaving behind the empty husk of the prey Others grind the prey to pulp using the chelicerae and the bases of the pedipalps while flooding it with enzymes in these species the chelicerae and the bases of the pedipalps form a preoral cavity that holds the food they are processing 13 The stomach in the cephalothorax acts as a pump that sends the food deeper into the digestive system The midgut bears many digestive ceca compartments with no other exit that extract nutrients from the food most are in the abdomen which is dominated by the digestive system but a few are found in the cephalothorax 13 Most spiders convert nitrogenous waste products into uric acid which can be excreted as a dry material Malphigian tubules little tubes extract these wastes from the blood in the hemocoel and dump them into the cloacal chamber from which they are expelled through the anus 13 Production of uric acid and its removal via Malphigian tubules are a water conserving feature that has evolved independently in several arthropod lineages that can live far away from water 20 for example the tubules of insects and arachnids develop from completely different parts of the embryo 14 However a few primitive spiders the suborder Mesothelae and infraorder Mygalomorphae retain the ancestral arthropod nephridia little kidneys 13 which use large amounts of water to excrete nitrogenous waste products as ammonia 20 Central nervous system The basic arthropod central nervous system consists of a pair of nerve cords running below the gut with paired ganglia as local control centers in all segments a brain formed by fusion of the ganglia for the head segments ahead of and behind the mouth so that the esophagus is encircled by this conglomeration of ganglia 21 Except for the primitive Mesothelae of which the Liphistiidae are the sole surviving family spiders have the much more centralized nervous system that is typical of arachnids all the ganglia of all segments behind the esophagus are fused so that the cephalothorax is largely filled with nervous tissue and there are no ganglia in the abdomen 13 14 21 in the Mesothelae the ganglia of the abdomen and the rear part of the cephalothorax remain unfused 17 Despite the relatively small central nervous system some spiders like Portia exhibit complex behaviour including the ability to use a trial and error approach 22 23 24 Sense organs Eyes Main article Spider vision nbsp This jumping spider s main ocelli center pair are very acute The outer pair are secondary eyes and there are other pairs of secondary eyes on the sides and top of its head 25 nbsp Eyes of the jumping spider Plexippus paykulliSpiders have primarily four pairs of eyes on the top front area of the cephalothorax arranged in patterns that vary from one family to another 13 The principal pair at the front are of the type called pigment cup ocelli little eyes which in most arthropods are only capable of detecting the direction from which light is coming using the shadow cast by the walls of the cup However in spiders these eyes are capable of forming images 25 26 The other pairs called secondary eyes are thought to be derived from the compound eyes of the ancestral chelicerates but no longer have the separate facets typical of compound eyes Unlike the principal eyes in many spiders these secondary eyes detect light reflected from a reflective tapetum lucidum and wolf spiders can be spotted by torchlight reflected from the tapeta On the other hand the secondary eyes of jumping spiders have no tapeta 13 Other differences between the principal and secondary eyes are that the latter have rhabdomeres that point away from incoming light just like in vertebrates while the arrangement is the opposite in the former The principal eyes are also the only ones with eye muscles allowing them to move the retina Having no muscles the secondary eyes are immobile 27 The visual acuity of some jumping spiders exceeds by a factor of ten that of dragonflies which have by far the best vision among insects citation needed This acuity is achieved by a telephotographic series of lenses a four layer retina and the ability to swivel the eyes and integrate images from different stages in the scan citation needed The downside is that the scanning and integrating processes are relatively slow 22 There are spiders with a reduced number of eyes the most common having six eyes example Periegops suterii with a pair of eyes absent on the anterior median line 28 Other species have four eyes and members of the Caponiidae family can have as few as two 29 Cave dwelling species have no eyes or possess vestigial eyes incapable of sight citation needed Other senses As with other arthropods spiders cuticles would block out information about the outside world except that they are penetrated by many sensors or connections from sensors to the nervous system In fact spiders and other arthropods have modified their cuticles into elaborate arrays of sensors Various touch sensors mostly bristles called setae respond to different levels of force from strong contact to very weak air currents Chemical sensors provide equivalents of taste and smell often by means of setae 25 An adult Araneus may have up to 1 000 such chemosensitive setae most on the tarsi of the first pair of legs Males have more chemosensitive bristles on their pedipalps than females They have been shown to be responsive to sex pheromones produced by females both contact and air borne 30 The jumping spider Evarcha culicivora uses the scent of blood from mammals and other vertebrates which is obtained by capturing blood filled mosquitoes to attract the opposite sex Because they are able to tell the sexes apart it is assumed the blood scent is mixed with pheromones 31 Spiders also have in the joints of their limbs slit sensillae that detect force and vibrations In web building spiders all these mechanical and chemical sensors are more important than the eyes while the eyes are most important to spiders that hunt actively 13 Like most arthropods spiders lack balance and acceleration sensors and rely on their eyes to tell them which way is up Arthropods proprioceptors sensors that report the force exerted by muscles and the degree of bending in the body and joints are well understood On the other hand little is known about what other internal sensors spiders or other arthropods may have 25 Some spiders use their webs for hearing where the giant webs function as extended and reconfigurable auditory sensors 32 Locomotion nbsp Image of a spider leg 1 coxa 2 trochanter 3 femur 4 patella 5 tibia 6 metatarsus 7 tarsus 8 clawsEach of the eight legs of a spider consists of seven distinct parts The part closest to and attaching the leg to the cephalothorax is the coxa the next segment is the short trochanter that works as a hinge for the following long segment the femur next is the spider s knee the patella which acts as the hinge for the tibia the metatarsus is next and it connects the tibia to the tarsus which may be thought of as a foot of sorts the tarsus ends in a claw made up of either two or three points depending on the family to which the spider belongs Although all arthropods use muscles attached to the inside of the exoskeleton to flex their limbs spiders and a few other groups still use hydraulic pressure to extend them a system inherited from their pre arthropod ancestors 33 The only extensor muscles in spider legs are located in the three hip joints bordering the coxa and the trochanter 34 As a result a spider with a punctured cephalothorax cannot extend its legs and the legs of dead spiders curl up 13 Spiders can generate pressures up to eight times their resting level to extend their legs 35 and jumping spiders can jump up to 50 times their own length by suddenly increasing the blood pressure in the third or fourth pair of legs 13 Although larger spiders use hydraulics to straighten their legs unlike smaller jumping spiders they depend on their flexor muscles to generate the propulsive force for their jumps 34 Most spiders that hunt actively rather than relying on webs have dense tufts of fine bristles between the paired claws at the tips of their legs These tufts known as scopulae consist of bristles whose ends are split into as many as 1 000 branches and enable spiders with scopulae to walk up vertical glass and upside down on ceilings It appears that scopulae get their grip from contact with extremely thin layers of water on surfaces 13 Spiders like most other arachnids keep at least four legs on the surface while walking or running 36 Silk production Main article Spider silk nbsp An orb weaver producing silk from its spinneretsThe abdomen has no appendages except those that have been modified to form one to four usually three pairs of short movable spinnerets which emit silk Each spinneret has many spigots each of which is connected to one silk gland There are at least six types of silk gland each producing a different type of silk 13 Spitting spiders also produce silk in modified venom glands 37 Silk is mainly composed of a protein very similar to that used in insect silk It is initially a liquid and hardens not by exposure to air but as a result of being drawn out which changes the internal structure of the protein 38 It is similar in tensile strength to nylon and biological materials such as chitin collagen and cellulose but is much more elastic In other words it can stretch much further before breaking or losing shape 13 Some spiders have a cribellum a modified spinneret with up to 40 000 spigots each of which produces a single very fine fiber The fibers are pulled out by the calamistrum a comblike set of bristles on the jointed tip of the cribellum and combined into a composite woolly thread that is very effective in snagging the bristles of insects The earliest spiders had cribella which produced the first silk capable of capturing insects before spiders developed silk coated with sticky droplets However most modern groups of spiders have lost the cribellum 13 Even species that do not build webs to catch prey use silk in several ways as wrappers for sperm and for fertilized eggs as a safety rope for nest building and as parachutes by the young of some species 13 Reproduction and life cycle Further information Spider cannibalism source source source source source source source source Mating behaviour of Neriene radiataSpiders reproduce sexually and fertilization is internal but indirect in other words the sperm is not inserted into the female s body by the male s genitals but by an intermediate stage Unlike many land living arthropods 39 male spiders do not produce ready made spermatophores packages of sperm but spin small sperm webs onto which they ejaculate and then transfer the sperm to special syringe styled structures palpal bulbs or palpal organs borne on the tips of the pedipalps of mature males When a male detects signs of a female nearby he checks whether she is of the same species and whether she is ready to mate for example in species that produce webs or safety ropes the male can identify the species and sex of these objects by smell 13 Spiders generally use elaborate courtship rituals to prevent the large females from eating the small males before fertilization except where the male is so much smaller that he is not worth eating In web weaving species precise patterns of vibrations in the web are a major part of the rituals while patterns of touches on the female s body are important in many spiders that hunt actively and may hypnotize the female Gestures and dances by the male are important for jumping spiders which have excellent eyesight If courtship is successful the male injects his sperm from the palpal bulbs into the female via one or two openings on the underside of her abdomen 13 Spider fertilization systems nbsp Haplogyne or non entelegyne nbsp EntelegyneSchematic diagrams showing sperm entering and being stored in the spermathecae eggs leaving the ovaries and being fertilized and finally a fertilized egg leaving the female s body Female spiders reproductive tracts are arranged in one of two ways The ancestral arrangement haplogyne or non entelegyne consists of a single genital opening leading to two seminal receptacles spermathecae in which females store sperm In the more advanced arrangement entelegyne there are two further openings leading directly to the spermathecae creating a flow through system rather than a first in first out one Eggs are as a general rule only fertilized during oviposition when the stored sperm is released from its chamber rather than in the ovarian cavity 40 A few exceptions exist such as Parasteatoda tepidariorum In these species the female appears to be able to activate the dormant sperm before oviposition allowing them to migrate to the ovarian cavity where fertilization occurs 41 42 43 The only known example of direct fertilization between male and female is an Israeli spider Harpactea sadistica which has evolved traumatic insemination In this species the male will penetrate its pedipalps through the female s body wall and inject his sperm directly into her ovaries where the embryos inside the fertilized eggs will start to develop before being laid 44 Males of the genus Tidarren amputate one of their palps before maturation and enter adult life with one palp only The palps are 20 of the male s body mass in this species and detaching one of the two improves mobility In the Yemeni species Tidarren argo the remaining palp is then torn off by the female The separated palp remains attached to the female s epigynum for about four hours and apparently continues to function independently In the meantime the female feeds on the palpless male 45 In over 60 of cases the female of the Australian redback spider kills and eats the male after it inserts its second palp into the female s genital opening in fact the males co operate by trying to impale themselves on the females fangs Observation shows that most male redbacks never get an opportunity to mate and the lucky ones increase the likely number of offspring by ensuring that the females are well fed 46 However males of most species survive a few matings limited mainly by their short life spans Some even live for a while in their mates webs 47 nbsp The tiny male of the golden orb weaver Trichonephila clavipes near the top of the leaf is protected from the female by producing the right vibrations in the web and may be too small to be worth eating nbsp Orange spider egg sac hanging from ceiling nbsp Gasteracantha mammosa spiderlings next to their eggs capsule nbsp Wolf spider carrying its young on its abdomenFemales lay up to 3 000 eggs in one or more silk egg sacs 13 which maintain a fairly constant humidity level 47 In some species the females die afterwards but females of other species protect the sacs by attaching them to their webs hiding them in nests carrying them in the chelicerae or attaching them to the spinnerets and dragging them along 13 Baby spiders pass all their larval stages inside the egg sac and emerge as spiderlings very small and sexually immature but similar in shape to adults Some spiders care for their young for example a wolf spider s brood clings to rough bristles on the mother s back 13 and females of some species respond to the begging behaviour of their young by giving them their prey provided it is no longer struggling or even regurgitate food 47 Like other arthropods spiders have to molt to grow as their cuticle skin cannot stretch 48 In some species males mate with newly molted females which are too weak to be dangerous to the males 47 Most spiders live for only one to two years although some tarantulas can live in captivity for over 20 years 13 49 and an Australian female trapdoor spider was documented to have lived in the wild for 43 years dying of a parasitic wasp attack 50 Size nbsp Goliath birdeater Theraphosa blondi the largest spider by massSpiders occur in a large range of sizes The smallest Patu digua from Colombia are less than 0 37 mm 0 015 in in body length The largest and heaviest spiders occur among tarantulas which can have body lengths up to 90 mm 3 5 in and leg spans up to 250 mm 9 8 in 51 Coloration Only three classes of pigment ommochromes bilins and guanine have been identified in spiders although other pigments have been detected but not yet characterized Melanins carotenoids and pterins very common in other animals are apparently absent In some species the exocuticle of the legs and prosoma is modified by a tanning process resulting in a brown coloration 52 Bilins are found for example in Micrommata virescens resulting in its green color Guanine is responsible for the white markings of the European garden spider Araneus diadematus It is in many species accumulated in specialized cells called guanocytes In genera such as Tetragnatha Leucauge Argyrodes or Theridiosoma guanine creates their silvery appearance While guanine is originally an end product of protein metabolism its excretion can be blocked in spiders leading to an increase in its storage 52 Structural colors occur in some species which are the result of the diffraction scattering or interference of light for example by modified setae or scales The white prosoma of Argiope results from bristles reflecting the light Lycosa and Josa both have areas of modified cuticle that act as light reflectors 52 The peacock spiders of Australia genus Maratus are notable for their bright structural colours in the males While in many spiders color is fixed throughout their lifespan in some groups color may be variable in response to environmental and internal conditions 52 Choice of prey may be able to alter the color of spiders For example the abdomen of Theridion grallator will become orange if the spider ingests certain species of Diptera and adult Lepidoptera but if it consumes Homoptera or larval Lepidoptera then the abdomen becomes green 53 Environmentally induced color changes may be morphological occurring over several days or physiological occurring near instantly Morphological changes require pigment synthesis and degradation In contrast to this physiological changes occur by changing the position of pigment containing cells 52 An example of morphological color changes is background matching Misumena vatia for instance can change its body color to match the substrate it lives on which makes it more difficult to be detected by prey 54 An example of physiological color change is observed in Cyrtophora cicatrosa which can change its body color from white to brown near instantly 52 Ecology and behaviorNon predatory feeding nbsp A jumping spider seen in Chennai Although spiders are generally regarded as predatory the jumping spider Bagheera kiplingi gets over 90 of its food from fairly solid plant material which acacias produce as part of a mutually beneficial relationship with a species of ant 55 Juveniles of some spiders in the families Anyphaenidae Corinnidae Clubionidae Thomisidae and Salticidae feed on plant nectar Laboratory studies show that they do so deliberately and over extended periods and periodically clean themselves while feeding These spiders also prefer sugar solutions to plain water which indicates that they are seeking nutrients Since many spiders are nocturnal the extent of nectar consumption by spiders may have been underestimated Nectar contains amino acids lipids vitamins and minerals in addition to sugars and studies have shown that other spider species live longer when nectar is available Feeding on nectar avoids the risks of struggles with prey and the costs of producing venom and digestive enzymes 56 Various species are known to feed on dead arthropods scavenging web silk and their own shed exoskeletons Pollen caught in webs may also be eaten and studies have shown that young spiders have a better chance of survival if they have the opportunity to eat pollen In captivity several spider species are also known to feed on bananas marmalade milk egg yolk and sausages 56 Capturing prey Main article Spider web nbsp Crab spider with prey nbsp The Phonognatha graeffei or leaf curling spider s web serves both as a trap and as a way of making its home in a leaf The best known method of prey capture is by means of sticky webs Varying placement of webs allows different species of spider to trap different insects in the same area for example flat horizontal webs trap insects that fly up from vegetation underneath while flat vertical webs trap insects in horizontal flight Web building spiders have poor vision but are extremely sensitive to vibrations 13 Females of the water spider Argyroneta aquatica build underwater diving bell webs that they fill with air and use for digesting prey molting mating and raising offspring They live almost entirely within the bells darting out to catch prey animals that touch the bell or the threads that anchor it 57 A few spiders use the surfaces of lakes and ponds as webs detecting trapped insects by the vibrations that these cause while struggling 13 Net casting spiders weave only small webs but then manipulate them to trap prey Those of the genus Hyptiotes and the family Theridiosomatidae stretch their webs and then release them when prey strike them but do not actively move their webs Those of the family Deinopidae weave even smaller webs hold them outstretched between their first two pairs of legs and lunge and push the webs as much as twice their own body length to trap prey and this move may increase the webs area by a factor of up to ten Experiments have shown that Deinopis spinosus has two different techniques for trapping prey backwards strikes to catch flying insects whose vibrations it detects and forward strikes to catch ground walking prey that it sees These two techniques have also been observed in other deinopids Walking insects form most of the prey of most deinopids but one population of Deinopis subrufa appears to live mainly on tipulid flies that they catch with the backwards strike 58 Mature female bolas spiders of the genus Mastophora build webs that consist of only a single trapeze line which they patrol They also construct a bolas made of a single thread tipped with a large ball of very wet sticky silk They emit chemicals that resemble the pheromones of moths and then swing the bolas at the moths Although they miss on about 50 of strikes they catch about the same weight of insects per night as web weaving spiders of similar size The spiders eat the bolas if they have not made a kill in about 30 minutes rest for a while and then make new bolas 59 60 Juveniles and adult males are much smaller and do not make bolas Instead they release different pheromones that attract moth flies and catch them with their front pairs of legs 61 nbsp A trapdoor spider in the genus Cyclocosmia an ambush predatorThe primitive Liphistiidae the trapdoor spiders of the family Ctenizidae and many tarantulas are ambush predators that lurk in burrows often closed by trapdoors and often surrounded by networks of silk threads that alert these spiders to the presence of prey 17 Other ambush predators do without such aids including many crab spiders 13 and a few species that prey on bees which see ultraviolet can adjust their ultraviolet reflectance to match the flowers in which they are lurking 52 Wolf spiders jumping spiders fishing spiders and some crab spiders capture prey by chasing it and rely mainly on vision to locate prey 13 nbsp Portia uses both webs and cunning versatile tactics to overcome prey 62 Some jumping spiders of the genus Portia hunt other spiders in ways that seem intelligent 22 outflanking their victims or luring them from their webs Laboratory studies show that Portia s instinctive tactics are only starting points for a trial and error approach from which these spiders learn very quickly how to overcome new prey species 62 However they seem to be relatively slow thinkers which is not surprising as their brains are vastly smaller than those of mammalian predators 22 nbsp An ant mimicking jumping spiderAnt mimicking spiders face several challenges they generally develop slimmer abdomens and false waists in the cephalothorax to mimic the three distinct regions tagmata of an ant s body they wave the first pair of legs in front of their heads to mimic antennae which spiders lack and to conceal the fact that they have eight legs rather than six they develop large color patches round one pair of eyes to disguise the fact that they generally have eight simple eyes while ants have two compound eyes they cover their bodies with reflective bristles to resemble the shiny bodies of ants In some spider species males and females mimic different ant species as female spiders are usually much larger than males Ant mimicking spiders also modify their behavior to resemble that of the target species of ant for example many adopt a zig zag pattern of movement ant mimicking jumping spiders avoid jumping and spiders of the genus Synemosyna walk on the outer edges of leaves in the same way as Pseudomyrmex Ant mimicry in many spiders and other arthropods may be for protection from predators that hunt by sight including birds lizards and spiders However several ant mimicking spiders prey either on ants or on the ants livestock such as aphids When at rest the ant mimicking crab spider Amyciaea does not closely resemble Oecophylla but while hunting it imitates the behavior of a dying ant to attract worker ants After a kill some ant mimicking spiders hold their victims between themselves and large groups of ants to avoid being attacked 63 Defense nbsp Threat display by a Sydney funnel web spider Atrax robustus There is strong evidence that spiders coloration is camouflage that helps them to evade their major predators birds and parasitic wasps both of which have good color vision Many spider species are colored so as to merge with their most common backgrounds and some have disruptive coloration stripes and blotches that break up their outlines In a few species such as the Hawaiian happy face spider Theridion grallator several coloration schemes are present in a ratio that appears to remain constant and this may make it more difficult for predators to recognize the species Most spiders are insufficiently dangerous or unpleasant tasting for warning coloration to offer much benefit However a few species with powerful venom large jaws or irritant bristles have patches of warning colors and some actively display these colors when threatened 52 64 Many of the family Theraphosidae which includes tarantulas and baboon spiders have urticating hairs on their abdomens and use their legs to flick them at attackers These bristles are fine setae bristles with fragile bases and a row of barbs on the tip The barbs cause intense irritation but there is no evidence that they carry any kind of venom 65 A few defend themselves against wasps by including networks of very robust threads in their webs giving the spider time to flee while the wasps are struggling with the obstacles 66 The golden wheeling spider Carparachne aureoflava of the Namibian desert escapes parasitic wasps by flipping onto its side and cartwheeling down sand dunes 67 Socialization Main article Social spider A few spider species that build webs live together in large colonies and show social behavior although not as complex as in social insects Anelosimus eximius in the family Theridiidae can form colonies of up to 50 000 individuals 68 The genus Anelosimus has a strong tendency towards sociality all known American species are social and species in Madagascar are at least somewhat social 69 Members of other species in the same family but several different genera have independently developed social behavior For example although Theridion nigroannulatum belongs to a genus with no other social species T nigroannulatum build colonies that may contain several thousand individuals that co operate in prey capture and share food 70 Other communal spiders include several Philoponella species family Uloboridae Agelena consociata family Agelenidae and Mallos gregalis family Dictynidae 71 Social predatory spiders need to defend their prey against kleptoparasites thieves and larger colonies are more successful in this 72 The herbivorous spider Bagheera kiplingi lives in small colonies which help to protect eggs and spiderlings 55 Even widow spiders genus Latrodectus which are notoriously cannibalistic have formed small colonies in captivity sharing webs and feeding together 73 In experiments spider species like Steatoda grossa Latrodectus hesperus and Eratigena agrestis stayed away from Myrmica rubra ant colonies These ants are predators and the pheromones they release for communication have a notable deterrent effect on these spider species 74 Web typesMain article Spider web nbsp The large orb web of Araneus diadematus European garden spider There is no consistent relationship between the classification of spiders and the types of web they build species in the same genus may build very similar or significantly different webs Nor is there much correspondence between spiders classification and the chemical composition of their silks Convergent evolution in web construction in other words use of similar techniques by remotely related species is rampant Orb web designs and the spinning behaviors that produce them are the best understood The basic radial then spiral sequence visible in orb webs and the sense of direction required to build them may have been inherited from the common ancestors of most spider groups 75 However the majority of spiders build non orb webs It used to be thought that the sticky orb web was an evolutionary innovation resulting in the diversification of the Orbiculariae Now however it appears that non orb spiders are a subgroup that evolved from orb web spiders and non orb spiders have over 40 more species and are four times as abundant as orb web spiders Their greater success may be because sphecid wasps which are often the dominant predators of spiders much prefer to attack spiders that have flat webs 76 Orb nbsp Nephila clavata a golden orb weaverAbout half the potential prey that hit orb webs escape A web has to perform three functions intercepting the prey intersection absorbing its momentum without breaking stopping and trapping the prey by entangling it or sticking to it retention No single design is best for all prey For example wider spacing of lines will increase the web s area and hence its ability to intercept prey but reduce its stopping power and retention closer spacing larger sticky droplets and thicker lines would improve retention but would make it easier for potential prey to see and avoid the web at least during the day However there are no consistent differences between orb webs built for use during the day and those built for use at night In fact there is no simple relationship between orb web design features and the prey they capture as each orb weaving species takes a wide range of prey 75 The hubs of orb webs where the spiders lurk are usually above the center as the spiders can move downwards faster than upwards If there is an obvious direction in which the spider can retreat to avoid its own predators the hub is usually offset towards that direction 75 Horizontal orb webs are fairly common despite being less effective at intercepting and retaining prey and more vulnerable to damage by rain and falling debris Various researchers have suggested that horizontal webs offer compensating advantages such as reduced vulnerability to wind damage reduced visibility to prey flying upwards because of the backlighting from the sky enabling oscillations to catch insects in slow horizontal flight However there is no single explanation for the common use of horizontal orb webs 75 Spiders often attach highly visible silk bands called decorations or stabilimenta to their webs Field research suggests that webs with more decorative bands captured more prey per hour 77 However a laboratory study showed that spiders reduce the building of these decorations if they sense the presence of predators 78 There are several unusual variants of orb web many of them convergently evolved including attachment of lines to the surface of water possibly to trap insects in or on the surface webs with twigs through their centers possibly to hide the spiders from predators ladderlike webs that appear most effective in catching moths However the significance of many variations is unclear 75 The orb weaving species Zygiella x notata for example is known for its characteristic missing sector orb web The missing sector contains a signal thread used to detect prey vibrations on the female s web 79 In 1973 Skylab 3 took two orb web spiders into space to test their web spinning capabilities in zero gravity At first both produced rather sloppy webs but they adapted quickly 80 Cobweb nbsp A funnel web Members of the family Theridiidae weave irregular tangled three dimensional webs popularly known as cobwebs There seems to be an evolutionary trend towards a reduction in the amount of sticky silk used leading to its total absence in some species The construction of cobwebs is less stereotyped than that of orb webs and may take several days 76 Other The Linyphiidae generally make horizontal but uneven sheets with tangles of stopping threads above Insects that hit the stopping threads fall onto the sheet or are shaken onto it by the spider and are held by sticky threads on the sheet until the spider can attack from below 81 Web design in zero gravity Many experiments have been conducted to study the effect of zero gravity on the design of spider webs In late 2020 reports of recent experiments were published that indicated that although web design was affected adversely in zero gravity conditions having access to a light source could orient spiders and enable them to build their normally shaped webs under such conditions 82 83 EvolutionMain article Spider evolution Fossil record nbsp Spider preserved in amberAlthough the fossil record of spiders is considered poor 84 almost 1000 species have been described from fossils 85 Because spiders bodies are quite soft the vast majority of fossil spiders have been found preserved in amber 85 The oldest known amber that contains fossil arthropods dates from 130 million years ago in the Early Cretaceous period In addition to preserving spiders anatomy in very fine detail pieces of amber show spiders mating killing prey producing silk and possibly caring for their young In a few cases amber has preserved spiders egg sacs and webs occasionally with prey attached 86 the oldest fossil web found so far is 100 million years old 87 Earlier spider fossils come from a few lagerstatten places where conditions were exceptionally suited to preserving fairly soft tissues 86 The oldest known exclusively terrestrial arachnid is the trigonotarbid Palaeotarbus jerami from about 420 million years ago in the Silurian period and had a triangular cephalothorax and segmented abdomen as well as eight legs and a pair of pedipalps 88 Attercopus fimbriunguis from 386 million years ago in the Devonian period bears the earliest known silk producing spigots and was therefore hailed as a spider at the time of its discovery 89 However these spigots may have been mounted on the underside of the abdomen rather than on spinnerets which are modified appendages and whose mobility is important in the building of webs Hence Attercopus and the similar Permian arachnid Permarachne may not have been true spiders and probably used silk for lining nests or producing egg cases rather than for building webs 3 The largest known fossil spider as of 2011 is the araneid Nephila jurassica from about 165 million years ago recorded from Daohuogo Inner Mongolia in China 90 Its body length is almost 25 mm i e almost one inch Several Carboniferous spiders were members of the Mesothelae a primitive group now represented only by the Liphistiidae 89 The mesothelid Paleothele montceauensis from the Late Carboniferous over 299 million years ago had five spinnerets 91 Although the Permian period 299 to 251 million years ago saw rapid diversification of flying insects there are very few fossil spiders from this period 89 The main groups of modern spiders Mygalomorphae and Araneomorphae first appear in the Triassic well before 200 million years ago Some Triassic mygalomorphs appear to be members of the family Hexathelidae whose modern members include the notorious Sydney funnel web spider and their spinnerets appear adapted for building funnel shaped webs to catch jumping insects Araneomorphae account for the great majority of modern spiders including those that weave the familiar orb shaped webs The Jurassic and Cretaceous periods provide a large number of fossil spiders including representatives of many modern families 89 According to a 2020 study using a molecular clock calibrated with 27 chelicerate fossils spiders most likely diverged from other chelicerates between 375 and 328 million years ago 92 External relationships The spiders Araneae are monophyletic i e a clade consisting of a last common ancestor and all of its descendants 93 There has been debate about what their closest evolutionary relatives are and how all of these evolved from the ancestral chelicerates which were marine animals 93 This 2019 cladogram illustrates the spiders phylogenetic relationships 94 95 Arachnids lack some features of other chelicerates including backward pointing mouths and gnathobases jaw bases at the bases of their legs 93 both of these features are part of the ancestral arthropod feeding system 96 Instead they have mouths that point forwards and downwards and all have some means of breathing air 93 Spiders Araneae are distinguished from other arachnid groups by several characteristics including spinnerets and in males pedipalps that are specially adapted for sperm transfer 97 Chelicerata Pycnogonida sea spiders nbsp Prosomapoda Xiphosura horseshoe crabs nbsp Eurypterida sea scorpions nbsp Arachnida Non pulmonates ticks harvestmen etc nbsp pulmonates Scorpiones nbsp Tetrapulmonata Araneae spiders nbsp Pedipalpi whip scorpions etc nbsp Internal relationships The cladogram shows the relation among spider suborders and families 98 Araneae Mesothelae LiphistiidaeOpisthothelae Mygalomorphae Atypoidea nbsp Avicularioidea nbsp Araneomorphae HypochilidaeAustrochiloidea GradungulidaeAustrochilidaeAraneoclada HaplogynaeEntelegynae nbsp TaxonomyMain article Spider taxonomy The order name Araneae derives from Latin aranea 99 borrowing Ancient Greek ἀraxnh arakhne from ἀraxnhs arakhnes 100 Spiders are divided into two suborders Mesothelae and Opisthothelae of which the latter contains two infraorders Mygalomorphae and Araneomorphae Some 50 356 living species of spiders order Araneae have been identified grouped into 132 families and 4 280 genera by arachnologists in 2022 1 Spider diversity 1 97 5 numbers are approximate FeaturesSuborder Infraorder Families Genera Species Segmented plates on top of abdomen 101 Ganglia in abdomen Spinnerets 101 Striking direction of fangs 13 Mesothelae 2 8 169 Yes Yes Four pairs in some species one pair fused under middle of abdomen Downwards and forwardsOpisthothelae Mygalomorphae 31 368 3 327 Only in some fossils No One two or three pairs under rear of abdomenOpisthothelae Araneomorphae 99 3 899 46 770 From sides to center like pincersMesothelae Main article Mesothelae nbsp Ryuthela sasakii a member of the Liphistiidae 102 The only living members of the primitive Mesothelae are the family Liphistiidae found only in Southeast Asia China and Japan 97 Most of the Liphistiidae construct silk lined burrows with thin trapdoors although some species of the genus Liphistius build camouflaged silk tubes with a second trapdoor as an emergency exit Members of the genus Liphistius run silk tripwires outwards from their tunnels to help them detect approaching prey while those of the genus Heptathela do not and instead rely on their built in vibration sensors 103 Spiders of the genus Heptathela have no venom glands although they do have venom gland outlets on the fang tip 104 The extinct families Arthrolycosidae found in Carboniferous and Permian rocks and Arthromygalidae so far found only in Carboniferous rocks have been classified as members of the Mesothelae 105 Mygalomorphae Main article Mygalomorphae nbsp A Mexican red kneed tarantula Brachypelma hamoriiThe Mygalomorphae which first appeared in the Triassic period 89 are generally heavily built and hairy with large robust chelicerae and fangs technically spiders do not have true hairs but rather setae 106 97 Well known examples include tarantulas ctenizid trapdoor spiders and the Australasian funnel web spiders 13 Most spend the majority of their time in burrows and some run silk tripwires out from these but a few build webs to capture prey However mygalomorphs cannot produce the pirifom silk that the Araneomorphae use as an instant adhesive to glue silk to surfaces or to other strands of silk and this makes web construction more difficult for mygalomorphs Since mygalomorphs rarely balloon by using air currents for transport their populations often form clumps 97 In addition to arthropods some mygalomorphs are known to prey on frogs small mammals lizards snakes snails and small birds 107 108 Araneomorphae Main article Araneomorphae nbsp Leucauge venusta an orb web spiderIn addition to accounting for over 90 of spider species the Araneomorphae also known as the true spiders include orb web spiders the cursorial wolf spiders and jumping spiders 97 as well as the only known herbivorous spider Bagheera kiplingi 55 They are distinguished by having fangs that oppose each other and cross in a pinching action in contrast to the Mygalomorphae which have fangs that are nearly parallel in alignment 109 Human interactionMedia coverage and misconceptions Information about spiders in the media is often emphasizing how dangerous and unpleasant they are A recent study investigated the global spread of mis information on spiders using a high resolution global database of online newspaper articles on spider human interactions These reports covered stories of spider human encounters and bites published from 2010 to 2020 The study found that 47 of articles contained errors and 43 were sensationalist 110 Bites Main article Spider bite Although spiders are widely feared only a few species are dangerous to people 111 Spiders will only bite humans in self defense and few produce worse effects than a mosquito bite or bee sting 112 Most of those with medically serious bites such as recluse spiders genus Loxosceles and widow spiders genus Latrodectus would rather flee and bite only when trapped although this can easily arise by accident 113 114 The defensive tactics of Australian funnel web spiders family Atracidae include fang display Their venom although they rarely inject much has resulted in 13 attributed human deaths over 50 years 115 They have been deemed to be the world s most dangerous spiders on clinical and venom toxicity grounds 111 though this claim has also been attributed to the Brazilian wandering spider genus Phoneutria 116 There were about 100 reliably reported deaths from spider bites in the 20th century 117 compared to about 1 500 from jellyfish stings 118 Many alleged cases of spider bites may represent incorrect diagnoses 119 which would make it more difficult to check the effectiveness of treatments for genuine bites 120 A review published in 2016 agreed with this conclusion showing that 78 of 134 published medical case studies of supposed spider bites did not meet the necessary criteria for a spider bite to be verified In the case of the two genera with the highest reported number of bites Loxosceles and Latrodectus spider bites were not verified in over 90 of the reports Even when verification had occurred details of the treatment and its effects were often lacking 121 Silk Main article Spider silk Because spider silk is both light and very strong attempts are being made to produce it in goats milk and in the leaves of plants by means of genetic engineering 122 123 Arachnophobia Main article Arachnophobia Arachnophobia is a specific phobia it is the abnormal fear of spiders or anything reminiscent of spiders such as webs or spiderlike shapes It is one of the most common specific phobias 124 125 and some statistics show that 50 of women and 10 of men show symptoms 126 It may be an exaggerated form of an instinctive response that helped early humans to survive 127 or a cultural phenomenon that is most common in predominantly European societies 128 As food See also Fried spider nbsp Cooked tarantulas are considered a delicacy in Cambodia Spiders are used as food 129 Cooked tarantulas are considered a delicacy in Cambodia 130 and by the Piaroa Indians of southern Venezuela provided the highly irritant bristles the spiders main defense system are removed first 131 Spiders in cultureMain article Cultural depictions of spiders nbsp This Moche ceramic depicts a spider and dates from around 300 CE Spiders have been the focus of stories and mythologies of various cultures for centuries 132 Uttu the ancient Sumerian goddess of weaving was envisioned as a spider spinning her web 133 134 According to her main myth she resisted her father Enki s sexual advances by ensconcing herself in her web 134 but let him in after he promised her fresh produce as a marriage gift 134 thereby allowing him to intoxicate her with beer and rape her 134 Enki s wife Ninhursag heard Uttu s screams and rescued her 134 removing Enki s semen from her vagina and planting it in the ground to produce eight previously nonexistent plants 134 In a story told by the Roman poet Ovid in his Metamorphoses Arachne Ancient Greek for spider was a Lydian girl who challenged the goddess Athena to a weaving contest 135 136 Arachne won but Athena destroyed her tapestry out of jealousy 136 137 causing Arachne to hang herself 136 137 In an act of mercy Athena brought Arachne back to life as the first spider 136 137 Stories about the trickster spider Anansi are prominent in the folktales of West Africa and the Caribbean 138 In some cultures spiders have symbolized patience due to their hunting technique of setting webs and waiting for prey as well as mischief and malice due to their venomous bites 139 The Italian tarantella is a dance to rid the young woman of the lustful effects of a spider bite Web spinning also caused the association of the spider with creation myths as they seem to have the ability to produce their own worlds 140 Dreamcatchers are depictions of spiderwebs The Moche people of ancient Peru worshipped nature 141 They placed emphasis on animals and often depicted spiders in their art 142 See alsoArachnidism Glossary of spider terms List of animals that produce silk List of endangered spiders Spider taxonomy ToxinsCitations a b c d Currently valid spider genera and species World Spider Catalog Natural History Museum Bern Retrieved 24 November 2023 Cushing P E 2008 Spiders Arachnida Araneae In Capinera J L ed Encyclopedia of Entomology Springer p 3496 doi 10 1007 978 1 4020 6359 6 4320 ISBN 978 1 4020 6242 1 a b Selden P A amp Shear W A December 2008 Fossil evidence for the origin of spider spinnerets PNAS 105 52 20781 85 Bibcode 2008PNAS 10520781S doi 10 1073 pnas 0809174106 PMC 2634869 PMID 19104044 Sebastin P A Peter K V eds 2009 Spiders of India Universities Press Orient Blackswan ISBN 978 81 7371 641 6 a b Dimitrov Dimitar Hormiga Gustavo 7 January 2021 Spider Diversification Through Space and Time Annual Review of Entomology 66 1 225 241 doi 10 1146 annurev ento 061520 083414 ISSN 0066 4170 PMID 32822555 S2CID 221235817 Retrieved 10 December 2021 Foelix Rainer F 1996 Biology of Spiders New York Oxford University Press p 3 ISBN 978 0 19 509593 7 Shultz Stanley Shultz Marguerite 2009 The Tarantula Keeper s Guide Hauppauge New York Barron s p 23 ISBN 978 0 7641 3885 0 Meehan Christopher J Olson Eric J Reudink Matthew W Kyser T Kurt Curry Robert L 2009 Herbivory in a spider through exploitation of an ant plant mutualism Current Biology 19 19 R892 93 doi 10 1016 j cub 2009 08 049 PMID 19825348 S2CID 27885893 Nyffeler Martin Birkhofer Klaus 14 March 2017 An estimated 400 800 million tons of prey are annually killed by the global spider community The Science of Nature 104 30 30 Bibcode 2017SciNa 104 30N doi 10 1007 s00114 017 1440 1 PMC 5348567 PMID 28289774 Spider Origin and meaning of spider by Online Etymology Dictionary a b c Ruppert Fox amp Barnes 2004 pp 554 55 a b Ruppert Fox amp Barnes 2004 pp 518 22 a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai aj Ruppert Fox amp Barnes 2004 pp 571 84 a b c d e f g Ruppert Fox amp Barnes 2004 pp 559 64 a b Ruppert Fox amp Barnes 2004 pp 565 69 Ruppert Fox amp Barnes 2004 pp 527 28 a b c Coddington J A amp Levi H W 1991 Systematics and Evolution of Spiders Araneae Annu Rev Ecol Syst 22 565 92 doi 10 1146 annurev es 22 110191 003025 Barghusen L E Claussen D L Anderson M S Bailer A J 1 February 1997 The effects of temperature on the web building behaviour of the common house spider Achaearanea tepidariorum Functional Ecology 11 1 4 10 doi 10 1046 j 1365 2435 1997 00040 x Spiders Aranas Dr Sam Thelin Drsamchapala com Retrieved 31 October 2017 a b Ruppert Fox amp Barnes 2004 pp 529 30 a b Ruppert Fox amp Barnes 2004 pp 531 32 a b c d Harland D P amp Jackson R R 2000 Eight legged cats and how they see a review of recent research on jumping spiders Araneae Salticidae PDF Cimbebasia 16 231 40 Archived from the original PDF on 28 September 2006 Retrieved 11 October 2008 Wilcox R Stimson Jackson Robert R 1998 Cognitive Abilities of Araneophagic Jumping Spiders In Balda Russell P Pepperberg Irene M Kamil Alan C eds Animal cognition in nature the convergence of psychology and biology in laboratory and field Academic Press ISBN 978 0 12 077030 4 Retrieved 8 May 2016 Mason Betsy 28 October 2021 Spiders are much smarter than you think Knowable Magazine doi 10 1146 knowable 102821 1 S2CID 240206876 Retrieved 10 December 2021 a b c d Ruppert Fox amp Barnes 2004 pp 532 37 Ruppert Fox amp Barnes 2004 pp 578 80 Barth Friedrich G 2013 A Spider s World Senses and Behavior Springer ISBN 9783662048993 Deeleman Reinhold 2001 p 27 Brescovit Antonio D Sanchez Ruiz Alexander 6 October 2016 Descriptions of two new genera of the spider family Caponiidae Arachnida Araneae and an update of Tisentnops and Taintnops from Brazil and Chile ZooKeys 622 47 84 doi 10 3897 zookeys 622 8682 ISSN 1313 2989 PMC 5096409 PMID 27843380 Foelix Rainer F 2011 Biology of Spiders 3rd p b ed Oxford University Press pp 100 01 ISBN 978 0 19 973482 5 Vampire spiders use blood as perfume CBC News CBC ca Zhou J Lai J Menda G Stafstrom J A Miles C I Hoy R R and Miles R N 2022 Outsourced hearing in an orb weaving spider that uses its web as an auditory sensor Proceedings of the National Academy of Sciences 119 14 p e2122789119 Barnes R S K Calow P Olive P Golding D Spicer J 2001 Invertebrates with Legs the Arthropods and Similar Groups The Invertebrates A Synthesis Blackwell Publishing p 168 ISBN 978 0 632 04761 1 a b Weihmann Tom Gunther Michael Blickhan Reinhard 15 February 2012 Hydraulic Leg Extension Is Not Necessarily the Main Drive in Large Spiders The Journal of Experimental Biology 215 4 578 83 doi 10 1242 jeb 054585 ISSN 0022 0949 PMID 22279064 Parry D A amp Brown R H J 1959 The Hydraulic Mechanism of the Spider Leg PDF Journal of Experimental Biology 36 2 423 33 doi 10 1242 jeb 36 2 423 Ruppert Fox amp Barnes 2004 pp 325 49 Suter R B Stratton G E 2009 Spitting Performance Parameters and Their Biomechanical Implications in the Spitting Spider Scytodes thoracica Journal of Insect Science 9 62 1 15 doi 10 1673 031 009 6201 PMC 3011943 PMID 20050781 Vollrath F amp Knight D P 2001 Liquid crystalline spinning of spider silk Nature 410 6828 541 48 Bibcode 2001Natur 410 541V doi 10 1038 35069000 PMID 11279484 S2CID 205015549 Ruppert Fox amp Barnes 2004 pp 537 39 Foelix Rainer F 2011 Biology of Spiders 3rd p b ed Oxford University Press ISBN 978 0 19 973482 5 Fertilization occurs internally in the spider Achaearanea tepidariorum C Koch Complex Genital System of a Haplogyne Spider Arachnida Araneae Tetrablemmidae Indicates Internal Fertilization and Full Female Control Over Transferred Sperm Structure and function of the female reproductive system in three species of goblin spiders Arachnida Araneae Oonopidae Rezac M August 2009 The spider Harpactea sadistica co evolution of traumatic insemination and complex female genital morphology in spiders Proc Biol Sci 276 1668 2697 701 doi 10 1098 rspb 2009 0104 PMC 2839943 PMID 19403531 Knoflach B amp van Harten A 2001 Tidarren argo sp nov Araneae Theridiidae and its exceptional copulatory behaviour emasculation male palpal organ as a mating plug and sexual cannibalism Journal of Zoology 254 4 449 59 doi 10 1017 S0952836901000954 Andrade Maydianne C B 2003 Risky mate search and male self sacrifice in redback spiders Behavioral Ecology 14 4 531 38 doi 10 1093 beheco arg015 hdl 1807 1012 a b c d Foelix Rainer F 1996 Reproduction Biology of Spiders 2nd ed Oxford University Press US pp 176 212 ISBN 978 0 19 509594 4 Ruppert 523 24 Foelix Rainer F 1996 Biology of Spiders Oxford University Press pp 232 33 ISBN 978 0 674 07431 6 World s oldest known spider dies at 43 after a quiet life underground The Guardian 30 April 2018 Retrieved 30 April 2018 Levi Herbert W and Levi Lorna R 2001 Spiders and their Kin 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arachnophobia Fritscher Lisa 3 June 2009 Spider Fears or Arachnophobia Phobias About com Archived from the original on 19 June 2009 Retrieved 2 August 2009 Arachnophobia or fear of spiders is one of the most common specific phobias The 10 Most Common Phobias Did You Know 10 Most Common Phobias Archived from the original on 3 September 2009 Retrieved 2 August 2009 Probably the most recognized of the 10 most common phobias arachnophobia is the fear of spiders The statistics clearly show that more than 50 of women and 10 of men show signs of this leader on the 10 most common phobias list Friedenberg J amp Silverman G 2005 Cognitive Science An Introduction to the Study of Mind Sage pp 244 45 ISBN 978 1 4129 2568 6 Davey G C L 1994 The Disgusting Spider The Role of Disease and Illness in the Perpetuation of Fear of Spiders Society and Animals 2 1 17 25 doi 10 1163 156853094X00045 Costa Neto E M Grabowski N T 27 November 2020 Edible arachnids and myriapods worldwide updated list nutritional profile and food hygiene implications Journal of Insects as Food and Feed 7 3 261 279 doi 10 3920 JIFF2020 0046 ISSN 2352 4588 S2CID 229391382 Ray N 2002 Lonely Planet Cambodia Lonely Planet Publications p 308 ISBN 978 1 74059 111 9 Weil C 2006 Fierce Food Plume ISBN 978 0 452 28700 6 De Vos Gail 1996 Tales Rumors and Gossip Exploring Contemporary Folk Literature in Grades 7 12 Libraries Unlimited p 186 ISBN 978 1 56308 190 3 Black Jeremy Green Anthony 1992 Gods Demons and Symbols of Ancient Mesopotamia An Illustrated Dictionary London England The British Museum Press p 182 ISBN 978 0 7141 1705 8 a b c d e f Jacobsen Thorkild 1987 The Harps that Once Sumerian Poetry in Translation New Haven Connecticut Yale University Press p 184 ISBN 978 0 300 07278 5 Norton Elizabeth 2013 Aspects of Ecphrastic Technique in Ovid s Metamorphoses Newcastle upon Tyne England Cambridge Scholars Publishing p 166 ISBN 978 1 4438 4271 6 a b c d Harries Byron 1990 The spinner and the poet Arachne in Ovid s Metamorphoses The Cambridge Classical Journal 36 64 82 doi 10 1017 S006867350000523X a b c Leach Eleanor Winsor January 1974 Ekphrasis and the Theme of Artistic Failure in Ovid s Metamorphoses Ramus 3 2 102 42 doi 10 1017 S0048671X00004549 S2CID 29668658 Haase Donald 2008 The Greenwood Encyclopedia of Folktales and Fairy Tales Santa Barbara California Greenwood Publishing Group p 31 ISBN 978 0 313 33441 2 Garai Jana 1973 The Book of Symbols New York Simon amp Schuster ISBN 978 0 671 21773 0 De Laguna Frederica 2002 American Anthropology Papers from the American Anthropologist University of Nebraska Press p 455 ISBN 978 0 8032 8280 3 Benson Elizabeth The Mochica A Culture of Peru New York Praeger Press 1972 Berrin Katherine amp Larco Museum The Spirit of Ancient Peru Treasures from the Museo Arqueologico Rafael Larco Herrera New York Thames and Hudson 1997 General and cited referencesDeeleman Reinhold Christa L 2001 Forest Spiders of South East Asia With a Revision of the Sac and Ground Spiders Brill Publishers ISBN 978 9004119598 Ruppert E E Fox R S Barnes R D 2004 Invertebrate Zoology 7th ed Brooks Cole ISBN 978 0 03 025982 1 Further readingBilger Burkhard 5 March 2007 Spider Woman The New Yorker pp 66 73 Bristowe W S 1976 The World of Spiders Taplinger Publishing Company ISBN 978 0 8008 8598 4 OCLC 256272177 Crompton John 1950 The Life of the Spider New York Mentor OCLC 1979220 Hillyard Paul 1994 The Book of the Spider From Arachnophobia to the Love of Spiders New York Random House ISBN 978 0 679 40881 9 OCLC 35231232 Kaston B J Kaston Elizabeth 1953 How to Know the Spiders Pictured Keys for Determining the More Common Spiders with Suggestions for Collecting and Studying Them 1st ed Dubuque Iowa W C Brown Company OCLC 628203833 Main Barbara York 1975 Spiders Sydney Collins ISBN 978 0 00 211443 1 OCLC 123151744 Wise David A 1993 Spiders in Ecological Webs Cambridge Studies in Ecology Cambridge Cambridge University Press ISBN 978 0 521 32547 9 OCLC 25833874 External linksSpiders at Curlie Picture story about the jumping spider Aelurillus v insignitus New Mexico State University The Spiders of the Arid Southwest Online Videos of Jumping Spiders Salticids and other arachnids list of field guides to spiders from the International Field Guides database Spider hunts on YouTube Record breaking achievements by spiders and the scientists who study them Portal nbsp Arthropods Retrieved from https en wikipedia org w index php title Spider amp oldid 1193717965, wikipedia, wiki, book, books, library,

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